Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
M Chetan Kumar | 790 | 98.01% | 2 | 50.00% |
Andy Shevchenko | 16 | 1.99% | 2 | 50.00% |
Total | 806 | 4 |
// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (C) 2020-21 Intel Corporation. */ #include <linux/delay.h> #include <linux/device.h> #include <linux/io.h> #include <linux/io-64-nonatomic-lo-hi.h> #include <linux/slab.h> #include "iosm_ipc_mmio.h" #include "iosm_ipc_mux.h" /* Definition of MMIO offsets * note that MMIO_CI offsets are relative to end of chip info structure */ /* MMIO chip info size in bytes */ #define MMIO_CHIP_INFO_SIZE 60 /* CP execution stage */ #define MMIO_OFFSET_EXECUTION_STAGE 0x00 /* Boot ROM Chip Info struct */ #define MMIO_OFFSET_CHIP_INFO 0x04 #define MMIO_OFFSET_ROM_EXIT_CODE 0x40 #define MMIO_OFFSET_PSI_ADDRESS 0x54 #define MMIO_OFFSET_PSI_SIZE 0x5C #define MMIO_OFFSET_IPC_STATUS 0x60 #define MMIO_OFFSET_CONTEXT_INFO 0x64 #define MMIO_OFFSET_BASE_ADDR 0x6C #define MMIO_OFFSET_END_ADDR 0x74 #define MMIO_OFFSET_CP_VERSION 0xF0 #define MMIO_OFFSET_CP_CAPABILITIES 0xF4 /* Timeout in 50 msec to wait for the modem boot code to write a valid * execution stage into mmio area */ #define IPC_MMIO_EXEC_STAGE_TIMEOUT 50 /* check if exec stage has one of the valid values */ static bool ipc_mmio_is_valid_exec_stage(enum ipc_mem_exec_stage stage) { switch (stage) { case IPC_MEM_EXEC_STAGE_BOOT: case IPC_MEM_EXEC_STAGE_PSI: case IPC_MEM_EXEC_STAGE_EBL: case IPC_MEM_EXEC_STAGE_RUN: case IPC_MEM_EXEC_STAGE_CRASH: case IPC_MEM_EXEC_STAGE_CD_READY: return true; default: return false; } } void ipc_mmio_update_cp_capability(struct iosm_mmio *ipc_mmio) { u32 cp_cap; unsigned int ver; ver = ipc_mmio_get_cp_version(ipc_mmio); cp_cap = ioread32(ipc_mmio->base + ipc_mmio->offset.cp_capability); ipc_mmio->mux_protocol = ((ver >= IOSM_CP_VERSION) && (cp_cap & (UL_AGGR | DL_AGGR))) ? MUX_AGGREGATION : MUX_LITE; ipc_mmio->has_ul_flow_credit = (ver >= IOSM_CP_VERSION) && (cp_cap & UL_FLOW_CREDIT); } struct iosm_mmio *ipc_mmio_init(void __iomem *mmio, struct device *dev) { struct iosm_mmio *ipc_mmio = kzalloc(sizeof(*ipc_mmio), GFP_KERNEL); int retries = IPC_MMIO_EXEC_STAGE_TIMEOUT; enum ipc_mem_exec_stage stage; if (!ipc_mmio) return NULL; ipc_mmio->dev = dev; ipc_mmio->base = mmio; ipc_mmio->offset.exec_stage = MMIO_OFFSET_EXECUTION_STAGE; /* Check for a valid execution stage to make sure that the boot code * has correctly initialized the MMIO area. */ do { stage = ipc_mmio_get_exec_stage(ipc_mmio); if (ipc_mmio_is_valid_exec_stage(stage)) break; msleep(20); } while (retries-- > 0); if (!retries) { dev_err(ipc_mmio->dev, "invalid exec stage %X", stage); goto init_fail; } ipc_mmio->offset.chip_info = MMIO_OFFSET_CHIP_INFO; /* read chip info size and version from chip info structure */ ipc_mmio->chip_info_version = ioread8(ipc_mmio->base + ipc_mmio->offset.chip_info); /* Increment of 2 is needed as the size value in the chip info * excludes the version and size field, which are always present */ ipc_mmio->chip_info_size = ioread8(ipc_mmio->base + ipc_mmio->offset.chip_info + 1) + 2; if (ipc_mmio->chip_info_size != MMIO_CHIP_INFO_SIZE) { dev_err(ipc_mmio->dev, "Unexpected Chip Info"); goto init_fail; } ipc_mmio->offset.rom_exit_code = MMIO_OFFSET_ROM_EXIT_CODE; ipc_mmio->offset.psi_address = MMIO_OFFSET_PSI_ADDRESS; ipc_mmio->offset.psi_size = MMIO_OFFSET_PSI_SIZE; ipc_mmio->offset.ipc_status = MMIO_OFFSET_IPC_STATUS; ipc_mmio->offset.context_info = MMIO_OFFSET_CONTEXT_INFO; ipc_mmio->offset.ap_win_base = MMIO_OFFSET_BASE_ADDR; ipc_mmio->offset.ap_win_end = MMIO_OFFSET_END_ADDR; ipc_mmio->offset.cp_version = MMIO_OFFSET_CP_VERSION; ipc_mmio->offset.cp_capability = MMIO_OFFSET_CP_CAPABILITIES; return ipc_mmio; init_fail: kfree(ipc_mmio); return NULL; } enum ipc_mem_exec_stage ipc_mmio_get_exec_stage(struct iosm_mmio *ipc_mmio) { if (!ipc_mmio) return IPC_MEM_EXEC_STAGE_INVALID; return (enum ipc_mem_exec_stage)ioread32(ipc_mmio->base + ipc_mmio->offset.exec_stage); } void ipc_mmio_copy_chip_info(struct iosm_mmio *ipc_mmio, void *dest, size_t size) { if (ipc_mmio && dest) memcpy_fromio(dest, ipc_mmio->base + ipc_mmio->offset.chip_info, size); } enum ipc_mem_device_ipc_state ipc_mmio_get_ipc_state(struct iosm_mmio *ipc_mmio) { if (!ipc_mmio) return IPC_MEM_DEVICE_IPC_INVALID; return (enum ipc_mem_device_ipc_state)ioread32(ipc_mmio->base + ipc_mmio->offset.ipc_status); } enum rom_exit_code ipc_mmio_get_rom_exit_code(struct iosm_mmio *ipc_mmio) { if (!ipc_mmio) return IMEM_ROM_EXIT_FAIL; return (enum rom_exit_code)ioread32(ipc_mmio->base + ipc_mmio->offset.rom_exit_code); } void ipc_mmio_config(struct iosm_mmio *ipc_mmio) { if (!ipc_mmio) return; /* AP memory window (full window is open and active so that modem checks * each AP address) 0 means don't check on modem side. */ iowrite64(0, ipc_mmio->base + ipc_mmio->offset.ap_win_base); iowrite64(0, ipc_mmio->base + ipc_mmio->offset.ap_win_end); iowrite64(ipc_mmio->context_info_addr, ipc_mmio->base + ipc_mmio->offset.context_info); } void ipc_mmio_set_psi_addr_and_size(struct iosm_mmio *ipc_mmio, dma_addr_t addr, u32 size) { if (!ipc_mmio) return; iowrite64(addr, ipc_mmio->base + ipc_mmio->offset.psi_address); iowrite32(size, ipc_mmio->base + ipc_mmio->offset.psi_size); } void ipc_mmio_set_contex_info_addr(struct iosm_mmio *ipc_mmio, phys_addr_t addr) { if (!ipc_mmio) return; /* store context_info address. This will be stored in the mmio area * during IPC_MEM_DEVICE_IPC_INIT state via ipc_mmio_config() */ ipc_mmio->context_info_addr = addr; } int ipc_mmio_get_cp_version(struct iosm_mmio *ipc_mmio) { if (ipc_mmio) return ioread32(ipc_mmio->base + ipc_mmio->offset.cp_version); return -EFAULT; }
Information contained on this website is for historical information purposes only and does not indicate or represent copyright ownership.
Created with Cregit http://github.com/cregit/cregit
Version 2.0-RC1