1d288ab24SVarun Wadekar /* 2a9e0260cSVignesh Radhakrishnan * Copyright (c) 2015-2017, ARM Limited and Contributors. All rights reserved. 3d288ab24SVarun Wadekar * 482cb2c1aSdp-arm * SPDX-License-Identifier: BSD-3-Clause 5d288ab24SVarun Wadekar */ 6d288ab24SVarun Wadekar 709d40e0eSAntonio Nino Diaz #include <assert.h> 809d40e0eSAntonio Nino Diaz #include <errno.h> 909d40e0eSAntonio Nino Diaz 10d288ab24SVarun Wadekar #include <arch.h> 11d288ab24SVarun Wadekar #include <arch_helpers.h> 1209d40e0eSAntonio Nino Diaz #include <common/bl_common.h> 1309d40e0eSAntonio Nino Diaz #include <common/debug.h> 1409d40e0eSAntonio Nino Diaz #include <common/runtime_svc.h> 1509d40e0eSAntonio Nino Diaz #include <lib/mmio.h> 1609d40e0eSAntonio Nino Diaz 17d288ab24SVarun Wadekar #include <memctrl.h> 18a9e0260cSVignesh Radhakrishnan #include <tegra_platform.h> 19ee1ebbd1SIsla Mitchell #include <tegra_private.h> 20d288ab24SVarun Wadekar 21d288ab24SVarun Wadekar /******************************************************************************* 22d288ab24SVarun Wadekar * Common Tegra SiP SMCs 23d288ab24SVarun Wadekar ******************************************************************************/ 24d288ab24SVarun Wadekar #define TEGRA_SIP_NEW_VIDEOMEM_REGION 0x82000003 2578e2bd10SVarun Wadekar #define TEGRA_SIP_FIQ_NS_ENTRYPOINT 0x82000005 2678e2bd10SVarun Wadekar #define TEGRA_SIP_FIQ_NS_GET_CONTEXT 0x82000006 27a9e0260cSVignesh Radhakrishnan #define TEGRA_SIP_ENABLE_FAKE_SYSTEM_SUSPEND 0xC2000007 28a9e0260cSVignesh Radhakrishnan 29a9e0260cSVignesh Radhakrishnan /******************************************************************************* 30a9e0260cSVignesh Radhakrishnan * Fake system suspend mode control var 31a9e0260cSVignesh Radhakrishnan ******************************************************************************/ 32a9e0260cSVignesh Radhakrishnan extern uint8_t tegra_fake_system_suspend; 33a9e0260cSVignesh Radhakrishnan 34d288ab24SVarun Wadekar /******************************************************************************* 35d288ab24SVarun Wadekar * SoC specific SiP handler 36d288ab24SVarun Wadekar ******************************************************************************/ 37d288ab24SVarun Wadekar #pragma weak plat_sip_handler 38aeafc362SAnthony Zhou int32_t plat_sip_handler(uint32_t smc_fid, 39d288ab24SVarun Wadekar uint64_t x1, 40d288ab24SVarun Wadekar uint64_t x2, 41d288ab24SVarun Wadekar uint64_t x3, 42d288ab24SVarun Wadekar uint64_t x4, 431d49112bSAnthony Zhou const void *cookie, 44d288ab24SVarun Wadekar void *handle, 45d288ab24SVarun Wadekar uint64_t flags) 46d288ab24SVarun Wadekar { 471d49112bSAnthony Zhou /* unused parameters */ 481d49112bSAnthony Zhou (void)smc_fid; 491d49112bSAnthony Zhou (void)x1; 501d49112bSAnthony Zhou (void)x2; 511d49112bSAnthony Zhou (void)x3; 521d49112bSAnthony Zhou (void)x4; 531d49112bSAnthony Zhou (void)cookie; 541d49112bSAnthony Zhou (void)handle; 551d49112bSAnthony Zhou (void)flags; 561d49112bSAnthony Zhou 57d288ab24SVarun Wadekar return -ENOTSUP; 58d288ab24SVarun Wadekar } 59d288ab24SVarun Wadekar 60d288ab24SVarun Wadekar /******************************************************************************* 612d05f810SWayne Lin * This function is responsible for handling all SiP calls 62d288ab24SVarun Wadekar ******************************************************************************/ 6357d1e5faSMasahiro Yamada uintptr_t tegra_sip_handler(uint32_t smc_fid, 6457d1e5faSMasahiro Yamada u_register_t x1, 6557d1e5faSMasahiro Yamada u_register_t x2, 6657d1e5faSMasahiro Yamada u_register_t x3, 6757d1e5faSMasahiro Yamada u_register_t x4, 68d288ab24SVarun Wadekar void *cookie, 69d288ab24SVarun Wadekar void *handle, 7057d1e5faSMasahiro Yamada u_register_t flags) 71d288ab24SVarun Wadekar { 724c994002SAnthony Zhou uint32_t regval, local_x2_32 = (uint32_t)x2; 731d49112bSAnthony Zhou int32_t err; 74d288ab24SVarun Wadekar 75d288ab24SVarun Wadekar /* Check if this is a SoC specific SiP */ 76d288ab24SVarun Wadekar err = plat_sip_handler(smc_fid, x1, x2, x3, x4, cookie, handle, flags); 77aeafc362SAnthony Zhou if (err == 0) { 78aeafc362SAnthony Zhou 79c76c1b71SVarun Wadekar SMC_RET1(handle, (uint64_t)err); 80d288ab24SVarun Wadekar 81aeafc362SAnthony Zhou } else { 82aeafc362SAnthony Zhou 83d288ab24SVarun Wadekar switch (smc_fid) { 84d288ab24SVarun Wadekar 85d288ab24SVarun Wadekar case TEGRA_SIP_NEW_VIDEOMEM_REGION: 86d288ab24SVarun Wadekar 87d288ab24SVarun Wadekar /* 88d288ab24SVarun Wadekar * Check if Video Memory overlaps TZDRAM (contains bl31/bl32) 89d288ab24SVarun Wadekar * or falls outside of the valid DRAM range 90d288ab24SVarun Wadekar */ 914c994002SAnthony Zhou err = bl31_check_ns_address(x1, local_x2_32); 92aeafc362SAnthony Zhou if (err != 0) { 93aeafc362SAnthony Zhou SMC_RET1(handle, (uint64_t)err); 94aeafc362SAnthony Zhou } 95d288ab24SVarun Wadekar 96d288ab24SVarun Wadekar /* 97d288ab24SVarun Wadekar * Check if Video Memory is aligned to 1MB. 98d288ab24SVarun Wadekar */ 994c994002SAnthony Zhou if (((x1 & 0xFFFFFU) != 0U) || ((local_x2_32 & 0xFFFFFU) != 0U)) { 100d288ab24SVarun Wadekar ERROR("Unaligned Video Memory base address!\n"); 101*aa64c5fbSAnthony Zhou SMC_RET1(handle, (uint64_t)-ENOTSUP); 102d288ab24SVarun Wadekar } 103d288ab24SVarun Wadekar 104f5f64e4dSVarun Wadekar /* 105f5f64e4dSVarun Wadekar * The GPU is the user of the Video Memory region. In order to 106f5f64e4dSVarun Wadekar * transition to the new memory region smoothly, we program the 107f5f64e4dSVarun Wadekar * new base/size ONLY if the GPU is in reset mode. 108f5f64e4dSVarun Wadekar */ 109f5f64e4dSVarun Wadekar regval = mmio_read_32(TEGRA_CAR_RESET_BASE + 110f5f64e4dSVarun Wadekar TEGRA_GPU_RESET_REG_OFFSET); 111*aa64c5fbSAnthony Zhou if ((regval & GPU_RESET_BIT) == 0U) { 112f5f64e4dSVarun Wadekar ERROR("GPU not in reset! Video Memory setup failed\n"); 113*aa64c5fbSAnthony Zhou SMC_RET1(handle, (uint64_t)-ENOTSUP); 114f5f64e4dSVarun Wadekar } 115f5f64e4dSVarun Wadekar 116d288ab24SVarun Wadekar /* new video memory carveout settings */ 1174c994002SAnthony Zhou tegra_memctrl_videomem_setup(x1, local_x2_32); 118d288ab24SVarun Wadekar 119d288ab24SVarun Wadekar SMC_RET1(handle, 0); 120d288ab24SVarun Wadekar 12178e2bd10SVarun Wadekar /* 12278e2bd10SVarun Wadekar * The NS world registers the address of its handler to be 12378e2bd10SVarun Wadekar * used for processing the FIQ. This is normally used by the 12478e2bd10SVarun Wadekar * NS FIQ debugger driver to detect system hangs by programming 12578e2bd10SVarun Wadekar * a watchdog timer to fire a FIQ interrupt. 12678e2bd10SVarun Wadekar */ 12778e2bd10SVarun Wadekar case TEGRA_SIP_FIQ_NS_ENTRYPOINT: 12878e2bd10SVarun Wadekar 129aeafc362SAnthony Zhou if (x1 == 0U) { 13078e2bd10SVarun Wadekar SMC_RET1(handle, SMC_UNK); 131aeafc362SAnthony Zhou } 13278e2bd10SVarun Wadekar 13378e2bd10SVarun Wadekar /* 13478e2bd10SVarun Wadekar * TODO: Check if x1 contains a valid DRAM address 13578e2bd10SVarun Wadekar */ 13678e2bd10SVarun Wadekar 13778e2bd10SVarun Wadekar /* store the NS world's entrypoint */ 13878e2bd10SVarun Wadekar tegra_fiq_set_ns_entrypoint(x1); 13978e2bd10SVarun Wadekar 14078e2bd10SVarun Wadekar SMC_RET1(handle, 0); 14178e2bd10SVarun Wadekar 14278e2bd10SVarun Wadekar /* 14378e2bd10SVarun Wadekar * The NS world's FIQ handler issues this SMC to get the NS EL1/EL0 14478e2bd10SVarun Wadekar * CPU context when the FIQ interrupt was triggered. This allows the 14578e2bd10SVarun Wadekar * NS world to understand the CPU state when the watchdog interrupt 14678e2bd10SVarun Wadekar * triggered. 14778e2bd10SVarun Wadekar */ 14878e2bd10SVarun Wadekar case TEGRA_SIP_FIQ_NS_GET_CONTEXT: 14978e2bd10SVarun Wadekar 15078e2bd10SVarun Wadekar /* retrieve context registers when FIQ triggered */ 151aeafc362SAnthony Zhou (void)tegra_fiq_get_intr_context(); 15278e2bd10SVarun Wadekar 15378e2bd10SVarun Wadekar SMC_RET0(handle); 15478e2bd10SVarun Wadekar 155a9e0260cSVignesh Radhakrishnan case TEGRA_SIP_ENABLE_FAKE_SYSTEM_SUSPEND: 156a9e0260cSVignesh Radhakrishnan /* 157a9e0260cSVignesh Radhakrishnan * System suspend fake mode is set if we are on VDK and we make 158a9e0260cSVignesh Radhakrishnan * a debug SIP call. This mode ensures that we excercise debug 159a9e0260cSVignesh Radhakrishnan * path instead of the regular code path to suit the pre-silicon 160a9e0260cSVignesh Radhakrishnan * platform needs. These include replacing the call to WFI by 161a9e0260cSVignesh Radhakrishnan * a warm reset request. 162a9e0260cSVignesh Radhakrishnan */ 163aeafc362SAnthony Zhou if (tegra_platform_is_virt_dev_kit() != false) { 164a9e0260cSVignesh Radhakrishnan 165a9e0260cSVignesh Radhakrishnan tegra_fake_system_suspend = 1; 166a9e0260cSVignesh Radhakrishnan SMC_RET1(handle, 0); 167a9e0260cSVignesh Radhakrishnan } 168a9e0260cSVignesh Radhakrishnan 169a9e0260cSVignesh Radhakrishnan /* 170a9e0260cSVignesh Radhakrishnan * We return to the external world as if this SIP is not 171a9e0260cSVignesh Radhakrishnan * implemented in case, we are not running on VDK. 172a9e0260cSVignesh Radhakrishnan */ 173a9e0260cSVignesh Radhakrishnan break; 174a9e0260cSVignesh Radhakrishnan 175d288ab24SVarun Wadekar default: 176d288ab24SVarun Wadekar ERROR("%s: unhandled SMC (0x%x)\n", __func__, smc_fid); 177d288ab24SVarun Wadekar break; 178d288ab24SVarun Wadekar } 179aeafc362SAnthony Zhou } 180d288ab24SVarun Wadekar 181d288ab24SVarun Wadekar SMC_RET1(handle, SMC_UNK); 182d288ab24SVarun Wadekar } 183d288ab24SVarun Wadekar 184d288ab24SVarun Wadekar /* Define a runtime service descriptor for fast SMC calls */ 185d288ab24SVarun Wadekar DECLARE_RT_SVC( 186d288ab24SVarun Wadekar tegra_sip_fast, 187d288ab24SVarun Wadekar 1881d49112bSAnthony Zhou (OEN_SIP_START), 1891d49112bSAnthony Zhou (OEN_SIP_END), 1901d49112bSAnthony Zhou (SMC_TYPE_FAST), 1911d49112bSAnthony Zhou (NULL), 1921d49112bSAnthony Zhou (tegra_sip_handler) 193d288ab24SVarun Wadekar ); 194