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// SPDX-License-Identifier: GPL-2.0-only OR MIT
/* Copyright (c) 2023 Imagination Technologies Ltd. */
#include "pvr_device.h"
#include "pvr_fw.h"
#include "pvr_fw_mips.h"
#include "pvr_gem.h"
#include "pvr_rogue_mips.h"
#include "pvr_vm_mips.h"
#include <linux/elf.h>
#include <linux/err.h>
#include <linux/types.h>
#define ROGUE_FW_HEAP_MIPS_BASE 0xC0000000
#define ROGUE_FW_HEAP_MIPS_SHIFT 24 /* 16 MB */
#define ROGUE_FW_HEAP_MIPS_RESERVED_SIZE SZ_1M
/**
* process_elf_command_stream() - Process ELF firmware image and populate
* firmware sections
* @pvr_dev: Device pointer.
* @fw: Pointer to firmware image.
* @fw_code_ptr: Pointer to FW code section.
* @fw_data_ptr: Pointer to FW data section.
* @fw_core_code_ptr: Pointer to FW coremem code section.
* @fw_core_data_ptr: Pointer to FW coremem data section.
*
* Returns :
* * 0 on success, or
* * -EINVAL on any error in ELF command stream.
*/
static int
process_elf_command_stream(struct pvr_device *pvr_dev, const u8 *fw, u8 *fw_code_ptr,
u8 *fw_data_ptr, u8 *fw_core_code_ptr, u8 *fw_core_data_ptr)
{
struct elf32_hdr *header = (struct elf32_hdr *)fw;
struct elf32_phdr *program_header = (struct elf32_phdr *)(fw + header->e_phoff);
struct drm_device *drm_dev = from_pvr_device(pvr_dev);
u32 entry;
int err;
for (entry = 0; entry < header->e_phnum; entry++, program_header++) {
void *write_addr;
/* Only consider loadable entries in the ELF segment table */
if (program_header->p_type != PT_LOAD)
continue;
err = pvr_fw_find_mmu_segment(pvr_dev, program_header->p_vaddr,
program_header->p_memsz, fw_code_ptr, fw_data_ptr,
fw_core_code_ptr, fw_core_data_ptr, &write_addr);
if (err) {
drm_err(drm_dev,
"Addr 0x%x (size: %d) not found in any firmware segment",
program_header->p_vaddr, program_header->p_memsz);
return err;
}
/* Write to FW allocation only if available */
if (write_addr) {
memcpy(write_addr, fw + program_header->p_offset,
program_header->p_filesz);
memset((u8 *)write_addr + program_header->p_filesz, 0,
program_header->p_memsz - program_header->p_filesz);
}
}
return 0;
}
static int
pvr_mips_init(struct pvr_device *pvr_dev)
{
pvr_fw_heap_info_init(pvr_dev, ROGUE_FW_HEAP_MIPS_SHIFT, ROGUE_FW_HEAP_MIPS_RESERVED_SIZE);
return pvr_vm_mips_init(pvr_dev);
}
static void
pvr_mips_fini(struct pvr_device *pvr_dev)
{
pvr_vm_mips_fini(pvr_dev);
}
static int
pvr_mips_fw_process(struct pvr_device *pvr_dev, const u8 *fw,
u8 *fw_code_ptr, u8 *fw_data_ptr, u8 *fw_core_code_ptr, u8 *fw_core_data_ptr,
u32 core_code_alloc_size)
{
struct pvr_fw_device *fw_dev = &pvr_dev->fw_dev;
struct pvr_fw_mips_data *mips_data = fw_dev->processor_data.mips_data;
const struct pvr_fw_layout_entry *boot_code_entry;
const struct pvr_fw_layout_entry *boot_data_entry;
const struct pvr_fw_layout_entry *exception_code_entry;
const struct pvr_fw_layout_entry *stack_entry;
struct rogue_mipsfw_boot_data *boot_data;
dma_addr_t dma_addr;
u32 page_nr;
int err;
err = process_elf_command_stream(pvr_dev, fw, fw_code_ptr, fw_data_ptr, fw_core_code_ptr,
fw_core_data_ptr);
if (err)
return err;
boot_code_entry = pvr_fw_find_layout_entry(pvr_dev, MIPS_BOOT_CODE);
boot_data_entry = pvr_fw_find_layout_entry(pvr_dev, MIPS_BOOT_DATA);
exception_code_entry = pvr_fw_find_layout_entry(pvr_dev, MIPS_EXCEPTIONS_CODE);
if (!boot_code_entry || !boot_data_entry || !exception_code_entry)
return -EINVAL;
WARN_ON(pvr_gem_get_dma_addr(fw_dev->mem.code_obj->gem, boot_code_entry->alloc_offset,
&mips_data->boot_code_dma_addr));
WARN_ON(pvr_gem_get_dma_addr(fw_dev->mem.data_obj->gem, boot_data_entry->alloc_offset,
&mips_data->boot_data_dma_addr));
WARN_ON(pvr_gem_get_dma_addr(fw_dev->mem.code_obj->gem,
exception_code_entry->alloc_offset,
&mips_data->exception_code_dma_addr));
stack_entry = pvr_fw_find_layout_entry(pvr_dev, MIPS_STACK);
if (!stack_entry)
return -EINVAL;
boot_data = (struct rogue_mipsfw_boot_data *)(fw_data_ptr + boot_data_entry->alloc_offset +
ROGUE_MIPSFW_BOOTLDR_CONF_OFFSET);
WARN_ON(pvr_fw_object_get_dma_addr(fw_dev->mem.data_obj, stack_entry->alloc_offset,
&dma_addr));
boot_data->stack_phys_addr = dma_addr;
boot_data->reg_base = pvr_dev->regs_resource->start;
for (page_nr = 0; page_nr < ARRAY_SIZE(boot_data->pt_phys_addr); page_nr++) {
/* Firmware expects 4k pages, but host page size might be different. */
u32 src_page_nr = (page_nr * ROGUE_MIPSFW_PAGE_SIZE_4K) >> PAGE_SHIFT;
u32 page_offset = (page_nr * ROGUE_MIPSFW_PAGE_SIZE_4K) & ~PAGE_MASK;
boot_data->pt_phys_addr[page_nr] = mips_data->pt_dma_addr[src_page_nr] +
page_offset;
}
boot_data->pt_log2_page_size = ROGUE_MIPSFW_LOG2_PAGE_SIZE_4K;
boot_data->pt_num_pages = ROGUE_MIPSFW_MAX_NUM_PAGETABLE_PAGES;
boot_data->reserved1 = 0;
boot_data->reserved2 = 0;
return 0;
}
static int
pvr_mips_wrapper_init(struct pvr_device *pvr_dev)
{
struct pvr_fw_mips_data *mips_data = pvr_dev->fw_dev.processor_data.mips_data;
const u64 remap_settings = ROGUE_MIPSFW_BOOT_REMAP_LOG2_SEGMENT_SIZE;
u32 phys_bus_width;
int err = PVR_FEATURE_VALUE(pvr_dev, phys_bus_width, &phys_bus_width);
if (WARN_ON(err))
return err;
/* Currently MIPS FW only supported with physical bus width > 32 bits. */
if (WARN_ON(phys_bus_width <= 32))
return -EINVAL;
pvr_cr_write32(pvr_dev, ROGUE_CR_MIPS_WRAPPER_CONFIG,
(ROGUE_MIPSFW_REGISTERS_VIRTUAL_BASE >>
ROGUE_MIPSFW_WRAPPER_CONFIG_REGBANK_ADDR_ALIGN) |
ROGUE_CR_MIPS_WRAPPER_CONFIG_BOOT_ISA_MODE_MICROMIPS);
/* Configure remap for boot code, boot data and exceptions code areas. */
pvr_cr_write64(pvr_dev, ROGUE_CR_MIPS_ADDR_REMAP1_CONFIG1,
ROGUE_MIPSFW_BOOT_REMAP_PHYS_ADDR_IN |
ROGUE_CR_MIPS_ADDR_REMAP1_CONFIG1_MODE_ENABLE_EN);
pvr_cr_write64(pvr_dev, ROGUE_CR_MIPS_ADDR_REMAP1_CONFIG2,
(mips_data->boot_code_dma_addr &
~ROGUE_CR_MIPS_ADDR_REMAP1_CONFIG2_ADDR_OUT_CLRMSK) | remap_settings);
if (PVR_HAS_QUIRK(pvr_dev, 63553)) {
/*
* WA always required on 36 bit cores, to avoid continuous unmapped memory accesses
* to address 0x0.
*/
WARN_ON(phys_bus_width != 36);
pvr_cr_write64(pvr_dev, ROGUE_CR_MIPS_ADDR_REMAP5_CONFIG1,
ROGUE_CR_MIPS_ADDR_REMAP5_CONFIG1_MODE_ENABLE_EN);
pvr_cr_write64(pvr_dev, ROGUE_CR_MIPS_ADDR_REMAP5_CONFIG2,
(mips_data->boot_code_dma_addr &
~ROGUE_CR_MIPS_ADDR_REMAP5_CONFIG2_ADDR_OUT_CLRMSK) |
remap_settings);
}
pvr_cr_write64(pvr_dev, ROGUE_CR_MIPS_ADDR_REMAP2_CONFIG1,
ROGUE_MIPSFW_DATA_REMAP_PHYS_ADDR_IN |
ROGUE_CR_MIPS_ADDR_REMAP2_CONFIG1_MODE_ENABLE_EN);
pvr_cr_write64(pvr_dev, ROGUE_CR_MIPS_ADDR_REMAP2_CONFIG2,
(mips_data->boot_data_dma_addr &
~ROGUE_CR_MIPS_ADDR_REMAP2_CONFIG2_ADDR_OUT_CLRMSK) | remap_settings);
pvr_cr_write64(pvr_dev, ROGUE_CR_MIPS_ADDR_REMAP3_CONFIG1,
ROGUE_MIPSFW_CODE_REMAP_PHYS_ADDR_IN |
ROGUE_CR_MIPS_ADDR_REMAP3_CONFIG1_MODE_ENABLE_EN);
pvr_cr_write64(pvr_dev, ROGUE_CR_MIPS_ADDR_REMAP3_CONFIG2,
(mips_data->exception_code_dma_addr &
~ROGUE_CR_MIPS_ADDR_REMAP3_CONFIG2_ADDR_OUT_CLRMSK) | remap_settings);
/* Garten IDLE bit controlled by MIPS. */
pvr_cr_write64(pvr_dev, ROGUE_CR_MTS_GARTEN_WRAPPER_CONFIG,
ROGUE_CR_MTS_GARTEN_WRAPPER_CONFIG_IDLE_CTRL_META);
/* Turn on the EJTAG probe. */
pvr_cr_write32(pvr_dev, ROGUE_CR_MIPS_DEBUG_CONFIG, 0);
return 0;
}
static u32
pvr_mips_get_fw_addr_with_offset(struct pvr_fw_object *fw_obj, u32 offset)
{
struct pvr_device *pvr_dev = to_pvr_device(gem_from_pvr_gem(fw_obj->gem)->dev);
/* MIPS cacheability is determined by page table. */
return ((fw_obj->fw_addr_offset + offset) & pvr_dev->fw_dev.fw_heap_info.offset_mask) |
ROGUE_FW_HEAP_MIPS_BASE;
}
static bool
pvr_mips_has_fixed_data_addr(void)
{
return true;
}
const struct pvr_fw_defs pvr_fw_defs_mips = {
.init = pvr_mips_init,
.fini = pvr_mips_fini,
.fw_process = pvr_mips_fw_process,
.vm_map = pvr_vm_mips_map,
.vm_unmap = pvr_vm_mips_unmap,
.get_fw_addr_with_offset = pvr_mips_get_fw_addr_with_offset,
.wrapper_init = pvr_mips_wrapper_init,
.has_fixed_data_addr = pvr_mips_has_fixed_data_addr,
.irq = {
.enable_reg = ROGUE_CR_MIPS_WRAPPER_IRQ_ENABLE,
.status_reg = ROGUE_CR_MIPS_WRAPPER_IRQ_STATUS,
.clear_reg = ROGUE_CR_MIPS_WRAPPER_IRQ_CLEAR,
.event_mask = ROGUE_CR_MIPS_WRAPPER_IRQ_STATUS_EVENT_EN,
.clear_mask = ROGUE_CR_MIPS_WRAPPER_IRQ_CLEAR_EVENT_EN,
},
};
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