2018-12-26 19:56:00 +04:00
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# 启动
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2018-12-27 11:54:07 +04:00
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## 启动流程
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树莓派的启动流程如下:
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1. 第一阶段:第一级 bootloader 位于片上 ROM 中,它挂载 SD 卡中的 FAT32 启动分区,并载入第二级 bootloader。
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2. 第二阶段:第二级 bootloader 位于`bootcode.bin` 中,它将载入 GPU 固件代码,并启动 GPU,进入第三级 bootloader。
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3. GPU 固件:该阶段将运行 GPU 固件 `start.elf`,它会读取 `config.txt` 中的启动参数,并将内核镜像 `kernel8.img` 复制到 `0x80000` 上。
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4. CPU 代码:CPU 从 `0x80000` 处开始执行内核代码。
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> 参考:https://github.com/DieterReuter/workshop-raspberrypi-64bit-os/blob/master/part1-bootloader.md
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## linker.ld
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链接脚本位于 `kernel/src/arch/aarch64/boot/linker.ld`,主要内容如下:
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```
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SECTIONS {
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. = 0x80000; /* Raspbery Pi 3 Aarch64 (kernel8.img) load address */
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.boot : {
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KEEP(*(.text.boot)) /* from boot.S */
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}
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. = 0x100000; /* Load the kernel at this address. It's also kernel stack top address */
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bootstacktop = .;
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.text : {
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stext = .;
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*(.text.entry)
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*(.text .text.* .gnu.linkonce.t*)
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. = ALIGN(4K);
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etext = .;
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}
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/* ... */
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}
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```
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几个要点:
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* CPU 最先从 `.text.boot (0x80000)` 处开始执行。
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* 在 `boot.S` 中做好了必要的初始化后,将跳转到 `.text.entry/_start (0x100000)`,再从这里跳转到 Rust 代码 `rust_main()`。
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* `boot.S` 的偏移为 `0x80000`,Rust 代码的偏移为 `0x100000`。
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* 跳转到 `rust_main()` 后,`0x0~0x100000` 这段内存将被作为内核栈,大小为 1MB,栈顶即 `bootstacktop (0x100000)`。
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* `boot.S` 结束后还未启用 MMU,可直接访问物理地址。
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## boot.S
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2018-12-27 14:36:27 +04:00
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CPU 启动代码位于 `kernel/src/arch/aarch64/boot/boot.S`,负责初始化一些系统寄存器,并将当前异常级别(exception level)切换到 EL1。
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AArch64 有 4 个异常级别,相当于 x86 的特权级,分别为:
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* EL0: Applications.
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* EL1: OS kernel and associated functions that are typically described as privileged.
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* EL2: Hypervisor.
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* EL3: Secure monitor.
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在 RustOS 中,内核将运行在 EL1 上,用户程序将运行在 EL0 上。
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`boot.S` 的主要流程如下:
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2018-12-27 11:54:07 +04:00
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1. 获取核的编号,目前只使用 0 号核,其余核将被闲置:
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```armasm
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.section .text.boot
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boot:
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# read cpu affinity, start core 0, halt rest
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mrs x1, mpidr_el1
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and x1, x1, #3
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cbz x1, setup
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halt:
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# core affinity != 0, halt it
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wfe
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b halt
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```
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2018-12-27 14:36:27 +04:00
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2. 读取当前异常级别:
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2018-12-27 11:54:07 +04:00
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```armasm
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# read the current exception level into x0 (ref: C5.2.1)
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mrs x0, CurrentEL
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and x0, x0, #0b1100
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lsr x0, x0, #2
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```
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3. 如果当前位于 EL3,初始化一些 EL3 下的系统寄存器,并使用 `eret` 指令切换到 EL2:
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```armasm
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switch_to_el2:
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# switch to EL2 if we are in EL3. otherwise switch to EL1
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cmp x0, #2
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beq switch_to_el1
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# set-up SCR_EL3 (bits 0, 4, 5, 7, 8, 10) (A53: 4.3.42)
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mov x0, #0x5b1
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msr scr_el3, x0
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# set-up SPSR_EL3 (bits 0, 3, 6, 7, 8, 9) (ref: C5.2.20)
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mov x0, #0x3c9
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msr spsr_el3, x0
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# switch
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adr x0, switch_to_el1
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msr elr_el3, x0
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eret
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```
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4. 当前位于 EL2,初值化 EL2 下的系统寄存器,并使用 `eret` 指令切换到 EL1:
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```armasm
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switch_to_el1:
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# switch to EL1 if we are not already in EL1. otherwise continue with start
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cmp x0, #1
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beq set_stack
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# set the stack-pointer for EL1
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msr sp_el1, x1
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# set-up HCR_EL2, enable AArch64 in EL1 (bits 1, 31) (ref: D10.2.45)
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mov x0, #0x0002
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movk x0, #0x8000, lsl #16
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msr hcr_el2, x0
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# do not trap accessing SVE registers (ref: D10.2.30)
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msr cptr_el2, xzr
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# enable floating point and SVE (SIMD) (bits 20, 21) (ref: D10.2.29)
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mrs x0, cpacr_el1
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orr x0, x0, #(0x3 << 20)
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msr cpacr_el1, x0
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# Set SCTLR to known state (RES1: 11, 20, 22, 23, 28, 29) (ref: D10.2.100)
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mov x0, #0x0800
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movk x0, #0x30d0, lsl #16
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msr sctlr_el1, x0
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# set-up SPSR_EL2 (bits 0, 2, 6, 7, 8, 9) (ref: C5.2.19)
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mov x0, #0x3c5
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msr spsr_el2, x0
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# enable CNTP for EL1/EL0 (ref: D7.5.2, D7.5.13)
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# NOTE: This does not actually enable the counter stream.
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mrs x0, cnthctl_el2
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orr x0, x0, #3
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msr cnthctl_el2, x0
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msr cntvoff_el2, xzr
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# switch
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adr x0, set_stack
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msr elr_el2, x0
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eret
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```
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5. 当前位于 EL1,设置栈顶地址为 `_start (0x100000)`,清空 BSS 段的数据:
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```armasm
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set_stack:
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# set the current stack pointer
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mov sp, x1
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zero_bss:
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# load the start address and number of bytes in BSS section
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ldr x1, =sbss
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ldr x2, =__bss_length
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zero_bss_loop:
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# zero out the BSS section, 64-bits at a time
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cbz x2, zero_bss_loop_end
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str xzr, [x1], #8
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sub x2, x2, #8
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cbnz x2, zero_bss_loop
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zero_bss_loop_end:
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b _start
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```
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6. 最后跳转到 Rust 代码 `rust_main()`:
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```armasm
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.section .text.entry
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.globl _start
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_start:
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# jump to rust_main, which should not return. halt if it does
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bl rust_main
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b halt
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```
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