Adding upstream version 2.10.0+dfsg.upstream/2.10.0+dfsgupstream

Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>

1 files changed, 174 insertions, 0 deletions

diff --git a/plat/arm/board/n1sdp/n1sdp_bl31_setup.c b/plat/arm/board/n1sdp/n1sdp_bl31_setup.c
new file mode 100644
index 0000000..430aab6
--- /dev/null
+++ b/plat/arm/board/n1sdp/n1sdp_bl31_setup.c
@@ -0,0 +1,174 @@
+/*
+ * Copyright (c) 2018-2023, Arm Limited. All rights reserved.
+ *
+ * SPDX-License-Identifier: BSD-3-Clause
+ */
+
+#include <common/debug.h>
+#include <drivers/arm/css/css_mhu_doorbell.h>
+#include <drivers/arm/css/scmi.h>
+#include <drivers/arm/css/sds.h>
+#include <drivers/arm/gic600_multichip.h>
+#include <lib/mmio.h>
+#include <lib/utils.h>
+#include <plat/arm/common/plat_arm.h>
+
+#include "n1sdp_def.h"
+#include "n1sdp_private.h"
+#include <platform_def.h>
+
+/*
+ * Platform information structure stored in SDS.
+ * This structure holds information about platform's DDR
+ * size which will be used to zero out the memory before
+ * enabling the ECC capability as well as information
+ * about multichip setup
+ * 	- multichip mode
+ * 	- secondary_count
+ * 	- Local DDR size in GB, DDR memory in master board
+ * 	- Remote DDR size in GB, DDR memory in secondary board
+ */
+struct n1sdp_plat_info {
+	bool multichip_mode;
+	uint8_t secondary_count;
+	uint8_t local_ddr_size;
+	uint8_t remote_ddr_size;
+} __packed;
+
+static scmi_channel_plat_info_t n1sdp_scmi_plat_info = {
+	.scmi_mbx_mem = N1SDP_SCMI_PAYLOAD_BASE,
+	.db_reg_addr = PLAT_CSS_MHU_BASE + CSS_SCMI_MHU_DB_REG_OFF,
+	.db_preserve_mask = 0xfffffffe,
+	.db_modify_mask = 0x1,
+	.ring_doorbell = &mhu_ring_doorbell
+};
+
+static struct gic600_multichip_data n1sdp_multichip_data __init = {
+	.rt_owner_base = PLAT_ARM_GICD_BASE,
+	.rt_owner = 0,
+	.chip_count = 1,
+	.chip_addrs = {
+		PLAT_ARM_GICD_BASE >> 16,
+		PLAT_ARM_GICD_BASE >> 16
+	},
+	.spi_ids = {
+		{PLAT_ARM_GICD_BASE, 32, 511},
+		{PLAT_ARM_GICD_BASE, 512, 991}
+	}
+};
+
+static uintptr_t n1sdp_multichip_gicr_frames[3] = {
+	PLAT_ARM_GICR_BASE,
+	PLAT_ARM_GICR_BASE + PLAT_ARM_REMOTE_CHIP_OFFSET,
+	0
+};
+
+scmi_channel_plat_info_t *plat_css_get_scmi_info(unsigned int channel_id)
+{
+	return &n1sdp_scmi_plat_info;
+}
+
+const plat_psci_ops_t *plat_arm_psci_override_pm_ops(plat_psci_ops_t *ops)
+{
+	ops->pwr_domain_off = n1sdp_pwr_domain_off;
+	return css_scmi_override_pm_ops(ops);
+}
+
+/*
+ * N1SDP platform supports RDIMMs with ECC capability. To use the ECC
+ * capability, the entire DDR memory space has to be zeroed out before
+ * enabling the ECC bits in DMC620. Zeroing out several gigabytes of
+ * memory from SCP is quite time consuming so the following function
+ * is added to zero out the DDR memory from application processor which is
+ * much faster compared to SCP. Local DDR memory is zeroed out during BL2
+ * stage. If remote chip is connected, it's DDR memory is zeroed out here.
+ */
+
+void remote_dmc_ecc_setup(uint8_t remote_ddr_size)
+{
+	uint64_t remote_dram2_size;
+
+	remote_dram2_size = (remote_ddr_size * 1024UL * 1024UL * 1024UL) -
+				N1SDP_REMOTE_DRAM1_SIZE;
+	/* multichip setup */
+	INFO("Zeroing remote DDR memories\n");
+	zero_normalmem((void *)N1SDP_REMOTE_DRAM1_BASE,
+			N1SDP_REMOTE_DRAM1_SIZE);
+	flush_dcache_range(N1SDP_REMOTE_DRAM1_BASE, N1SDP_REMOTE_DRAM1_SIZE);
+	zero_normalmem((void *)N1SDP_REMOTE_DRAM2_BASE, remote_dram2_size);
+	flush_dcache_range(N1SDP_REMOTE_DRAM2_BASE, remote_dram2_size);
+
+	INFO("Enabling ECC on remote DMCs\n");
+	/* Set DMCs to CONFIG state before writing ERR0CTLR0 register */
+	mmio_write_32(N1SDP_REMOTE_DMC0_MEMC_CMD_REG,
+			N1SDP_DMC_MEMC_CMD_CONFIG);
+	mmio_write_32(N1SDP_REMOTE_DMC1_MEMC_CMD_REG,
+			N1SDP_DMC_MEMC_CMD_CONFIG);
+
+	/* Enable ECC in DMCs */
+	mmio_setbits_32(N1SDP_REMOTE_DMC0_ERR0CTLR0_REG,
+			N1SDP_DMC_ERR0CTLR0_ECC_EN);
+	mmio_setbits_32(N1SDP_REMOTE_DMC1_ERR0CTLR0_REG,
+			N1SDP_DMC_ERR0CTLR0_ECC_EN);
+
+	/* Set DMCs to READY state */
+	mmio_write_32(N1SDP_REMOTE_DMC0_MEMC_CMD_REG, N1SDP_DMC_MEMC_CMD_READY);
+	mmio_write_32(N1SDP_REMOTE_DMC1_MEMC_CMD_REG, N1SDP_DMC_MEMC_CMD_READY);
+}
+
+void n1sdp_bl31_multichip_setup(void)
+{
+	plat_arm_override_gicr_frames(n1sdp_multichip_gicr_frames);
+	gic600_multichip_init(&n1sdp_multichip_data);
+}
+
+void bl31_platform_setup(void)
+{
+	int ret;
+	struct n1sdp_plat_info plat_info;
+
+	ret = sds_init();
+	if (ret != SDS_OK) {
+		ERROR("SDS initialization failed\n");
+		panic();
+	}
+
+	ret = sds_struct_read(N1SDP_SDS_PLATFORM_INFO_STRUCT_ID,
+				N1SDP_SDS_PLATFORM_INFO_OFFSET,
+				&plat_info,
+				N1SDP_SDS_PLATFORM_INFO_SIZE,
+				SDS_ACCESS_MODE_NON_CACHED);
+	if (ret != SDS_OK) {
+		ERROR("Error getting platform info from SDS\n");
+		panic();
+	}
+	/* Validate plat_info SDS */
+	if ((plat_info.local_ddr_size == 0)
+		|| (plat_info.local_ddr_size > N1SDP_MAX_DDR_CAPACITY_GB)
+		|| (plat_info.remote_ddr_size > N1SDP_MAX_DDR_CAPACITY_GB)
+		|| (plat_info.secondary_count > N1SDP_MAX_SECONDARY_COUNT)) {
+		ERROR("platform info SDS is corrupted\n");
+		panic();
+	}
+
+	if (plat_info.multichip_mode) {
+		n1sdp_multichip_data.chip_count = plat_info.secondary_count + 1;
+		n1sdp_bl31_multichip_setup();
+	}
+	arm_bl31_platform_setup();
+
+	/* Check if remote memory is present */
+	if ((plat_info.multichip_mode) && (plat_info.remote_ddr_size != 0))
+		remote_dmc_ecc_setup(plat_info.remote_ddr_size);
+}
+
+#if defined(SPD_spmd) && (SPMC_AT_EL3 == 0)
+/*
+ * A dummy implementation of the platform handler for Group0 secure interrupt.
+ */
+int plat_spmd_handle_group0_interrupt(uint32_t intid)
+{
+	(void)intid;
+	return -1;
+}
+#endif /*defined(SPD_spmd) && (SPMC_AT_EL3 == 0)*/