#
# Copyright (c) 2005 Jakub Jermar
# All rights reserved.
#
# Redistribution and use in source and binary forms, with or without
# modification, are permitted provided that the following conditions
# are met:
#
# - Redistributions of source code must retain the above copyright
# notice, this list of conditions and the following disclaimer.
# - Redistributions in binary form must reproduce the above copyright
# notice, this list of conditions and the following disclaimer in the
# documentation and/or other materials provided with the distribution.
# - The name of the author may not be used to endorse or promote products
# derived from this software without specific prior written permission.
#
# THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
# IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
# OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
# IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
# INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
# NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
# DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
# THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
# THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#
#include <abi/asmtool.h>
#include <arch/arch.h>
#include <arch/cpu.h>
#include <arch/regdef.h>
#include <arch/boot/boot.h>
#include <arch/stack.h>
#include <arch/mm/mmu.h>
#include <arch/mm/tlb.h>
#include <arch/mm/tte.h>
#include <arch/mm/cache_spec.h>
#ifdef CONFIG_SMP
#include <arch/context_struct.h>
#endif
.register %g2, #scratch
.register %g3, #scratch
.section K_TEXT_START, "ax"
#define BSP_FLAG 1
/*
* 2^PHYSMEM_ADDR_SIZE is the size of the physical address space on
* a given processor.
*/
#if defined (US)
#define PHYSMEM_ADDR_SIZE 41
#elif defined (US3)
#define PHYSMEM_ADDR_SIZE 43
#endif
/*
* Here is where the kernel is passed control from the boot loader.
*
* The registers are expected to be in this state:
* - %o0 starting address of physical memory
* + bootstrap processor flag
* bits 63...1: physical memory starting address / 2
* bit 0: non-zero on BSP processor, zero on AP processors
* - %o1 bootinfo structure address (BSP only)
*
*
* Moreover, we depend on boot having established the following environment:
* - TLBs are on
* - identity mapping for the kernel image
*
*/
SYMBOL(kernel_image_start)
mov BSP_FLAG, %l0
and %o0, %l0, %l7 ! l7 <= bootstrap processor?
andn %o0, %l0, %l6 ! l6 <= start of physical memory
! Get bits (PHYSMEM_ADDR_SIZE - 1):13 of physmem_base.
srlx %l6, 13, %l5
! l5 <= physmem_base[(PHYSMEM_ADDR_SIZE - 1):13]
sllx %l5, 13 + (63 - (PHYSMEM_ADDR_SIZE - 1)), %l5
srlx %l5, 63 - (PHYSMEM_ADDR_SIZE - 1), %l5
/*
* Setup basic runtime environment.
*/
wrpr %g0, NWINDOWS - 2, %cansave ! set maximum saveable windows
wrpr %g0, 0, %canrestore ! get rid of windows we will
! never need again
wrpr %g0, 0, %otherwin ! make sure the window state is
! consistent
wrpr %g0, NWINDOWS - 1, %cleanwin ! prevent needless clean_window
! traps for kernel
wrpr %g0, 0, %wstate ! use default spill/fill trap
wrpr %g0, 0, %tl ! TL = 0, primary context
! register is used
wrpr %g0, PSTATE_PRIV_BIT, %pstate ! disable interrupts and disable
! 32-bit address masking
wrpr %g0, 0, %pil ! intialize %pil
/*
* Switch to kernel trap table.
*/
sethi %hi(trap_table), %g1
wrpr %g1, %lo(trap_table), %tba
/*
* Take over the DMMU by installing locked TTE entry identically
* mapping the first 4M of memory.
*
* In case of DMMU, no FLUSH instructions need to be issued. Because of
* that, the old DTLB contents can be demapped pretty straightforwardly
* and without causing any traps.
*/
wr %g0, ASI_DMMU, %asi
#define SET_TLB_DEMAP_CMD(r1, context_id) \
set (TLB_DEMAP_CONTEXT << TLB_DEMAP_TYPE_SHIFT) | (context_id << \
TLB_DEMAP_CONTEXT_SHIFT), %r1
! demap context 0
SET_TLB_DEMAP_CMD(g1, TLB_DEMAP_NUCLEUS)
stxa %g0, [%g1] ASI_DMMU_DEMAP
membar #Sync
#define SET_TLB_TAG(r1, context) \
set VMA | (context << TLB_TAG_ACCESS_CONTEXT_SHIFT), %r1
! write DTLB tag
SET_TLB_TAG(g1, MEM_CONTEXT_KERNEL)
stxa %g1, [VA_DMMU_TAG_ACCESS] %asi
membar #Sync
#ifdef CONFIG_VIRT_IDX_DCACHE
#define TTE_LOW_DATA(imm) (TTE_CP | TTE_CV | TTE_P | LMA | (imm))
#else /* CONFIG_VIRT_IDX_DCACHE */
#define TTE_LOW_DATA(imm) (TTE_CP | TTE_P | LMA | (imm))
#endif /* CONFIG_VIRT_IDX_DCACHE */
#define SET_TLB_DATA(r1, r2, imm) \
set TTE_LOW_DATA(imm), %r1; \
or %r1, %l5, %r1; \
mov PAGESIZE_4M, %r2; \
sllx %r2, TTE_SIZE_SHIFT, %r2; \
or %r1, %r2, %r1; \
mov 1, %r2; \
sllx %r2, TTE_V_SHIFT, %r2; \
or %r1, %r2, %r1;
! write DTLB data and install the kernel mapping
SET_TLB_DATA(g1, g2, TTE_L | TTE_W) ! use non-global mapping
stxa %g1, [%g0] ASI_DTLB_DATA_IN_REG
membar #Sync
/*
* Because we cannot use global mappings (because we want to have
* separate 64-bit address spaces for both the kernel and the
* userspace), we prepare the identity mapping also in context 1. This
* step is required by the code installing the ITLB mapping.
*/
! write DTLB tag of context 1 (i.e. MEM_CONTEXT_TEMP)
SET_TLB_TAG(g1, MEM_CONTEXT_TEMP)
stxa %g1, [VA_DMMU_TAG_ACCESS] %asi
membar #Sync
! write DTLB data and install the kernel mapping in context 1
SET_TLB_DATA(g1, g2, TTE_W) ! use non-global mapping
stxa %g1, [%g0] ASI_DTLB_DATA_IN_REG
membar #Sync
/*
* Now is time to take over the IMMU. Unfortunatelly, it cannot be done
* as easily as the DMMU, because the IMMU is mapping the code it
* executes.
*
* [ Note that brave experiments with disabling the IMMU and using the
* DMMU approach failed after a dozen of desparate days with only little
* success. ]
*
* The approach used here is inspired from OpenBSD. First, the kernel
* creates IMMU mapping for itself in context 1 (MEM_CONTEXT_TEMP) and
* switches to it. Context 0 (MEM_CONTEXT_KERNEL) can be demapped
* afterwards and replaced with the kernel permanent mapping. Finally,
* the kernel switches back to context 0 and demaps context 1.
*
* Moreover, the IMMU requires use of the FLUSH instructions. But that
* is OK because we always use operands with addresses already mapped by
* the taken over DTLB.
*/
set kernel_image_start, %g5
! write ITLB tag of context 1
SET_TLB_TAG(g1, MEM_CONTEXT_TEMP)
mov VA_DMMU_TAG_ACCESS, %g2
stxa %g1, [%g2] ASI_IMMU
flush %g5
! write ITLB data and install the temporary mapping in context 1
SET_TLB_DATA(g1, g2, 0) ! use non-global mapping
stxa %g1, [%g0] ASI_ITLB_DATA_IN_REG
flush %g5
! switch to context 1
mov MEM_CONTEXT_TEMP, %g1
stxa %g1, [VA_PRIMARY_CONTEXT_REG] %asi ! ASI_DMMU is correct here !!!
flush %g5
! demap context 0
SET_TLB_DEMAP_CMD(g1, TLB_DEMAP_NUCLEUS)
stxa %g0, [%g1] ASI_IMMU_DEMAP
flush %g5
! write ITLB tag of context 0
SET_TLB_TAG(g1, MEM_CONTEXT_KERNEL)
mov VA_DMMU_TAG_ACCESS, %g2
stxa %g1, [%g2] ASI_IMMU
flush %g5
! write ITLB data and install the permanent kernel mapping in context 0
SET_TLB_DATA(g1, g2, TTE_L) ! use non-global mapping
stxa %g1, [%g0] ASI_ITLB_DATA_IN_REG
flush %g5
! enter nucleus - using context 0
wrpr %g0, 1, %tl
! demap context 1
SET_TLB_DEMAP_CMD(g1, TLB_DEMAP_PRIMARY)
stxa %g0, [%g1] ASI_IMMU_DEMAP
flush %g5
! set context 0 in the primary context register
stxa %g0, [VA_PRIMARY_CONTEXT_REG] %asi ! ASI_DMMU is correct here !!!
flush %g5
! leave nucleus - using primary context, i.e. context 0
wrpr %g0, 0, %tl
brz %l7, 1f ! skip if you are not the bootstrap CPU
nop
/*
* Save physmem_base for use by the mm subsystem.
* %l6 contains starting physical address
*/
sethi %hi(physmem_base), %l4
stx %l6, [%l4 + %lo(physmem_base)]
/*
* Precompute kernel 8K TLB data template.
* %l5 contains starting physical address
* bits [(PHYSMEM_ADDR_SIZE - 1):13]
*/
sethi %hi(kernel_8k_tlb_data_template), %l4
ldx [%l4 + %lo(kernel_8k_tlb_data_template)], %l3
or %l3, %l5, %l3
stx %l3, [%l4 + %lo(kernel_8k_tlb_data_template)]
! flush the whole D-cache
set (DCACHE_SIZE - DCACHE_LINE_SIZE), %g1
stxa %g0, [%g1] ASI_DCACHE_TAG
0:
membar #Sync
subcc %g1, DCACHE_LINE_SIZE, %g1
bnz,pt %xcc, 0b
stxa %g0, [%g1] ASI_DCACHE_TAG
membar #Sync
/*
* So far, we have not touched the stack.
* It is a good idea to set the kernel stack to a known state now.
*/
sethi %hi(temporary_boot_stack), %sp
or %sp, %lo(temporary_boot_stack), %sp
sub %sp, STACK_BIAS, %sp
/*
* Call sparc64_pre_main(bootinfo)
*/
call sparc64_pre_main
mov %o1, %o0
/*
* Create the first stack frame.
*/
save %sp, -(STACK_WINDOW_SAVE_AREA_SIZE + STACK_ARG_SAVE_AREA_SIZE), %sp
flushw
add %g0, -STACK_BIAS, %fp
call main_bsp
nop
/* Not reached. */
0:
ba,a %xcc, 0b
1:
#ifdef CONFIG_SMP
/*
* Determine the width of the MID and save its mask to %g3. The width
* is
* * 5 for US and US-IIIi,
* * 10 for US3 except US-IIIi.
*/
#if defined(US)
mov 0x1f, %g3
#elif defined(US3)
mov 0x3ff, %g3
rdpr %ver, %g2
sllx %g2, 16, %g2
srlx %g2, 48, %g2
cmp %g2, IMPL_ULTRASPARCIII_I
move %xcc, 0x1f, %g3
#endif
/*
* Read MID from the processor.
*/
ldxa [%g0] ASI_ICBUS_CONFIG, %g1
srlx %g1, ICBUS_CONFIG_MID_SHIFT, %g1
and %g1, %g3, %g1
/*
* Active loop for APs until the BSP picks them up. A processor cannot
* leave the loop until the global variable 'waking_up_mid' equals its
* MID.
*/
set waking_up_mid, %g2
2:
ldx [%g2], %g3
cmp %g3, %g1
bne %xcc, 2b
nop
/*
* Configure stack for the AP.
* The AP is expected to use the stack saved
* in the ctx global variable.
*/
set bootstrap_stack_top, %g1
ldx [%g1], %o6
/*
* Create the first stack frame.
*/
save %sp, -(STACK_WINDOW_SAVE_AREA_SIZE + STACK_ARG_SAVE_AREA_SIZE), %sp
flushw
add %g0, -STACK_BIAS, %fp
call main_ap
nop
/* Not reached. */
#endif
0:
ba,a %xcc, 0b
.section K_DATA_START, "aw", @progbits
/*
* Create small stack to be used by the bootstrap processor. It is going to be
* used only for a very limited period of time, but we switch to it anyway,
* just to be sure we are properly initialized.
*/
#define INITIAL_STACK_SIZE 1024
.align STACK_ALIGNMENT
.space INITIAL_STACK_SIZE
.align STACK_ALIGNMENT
temporary_boot_stack:
.space STACK_WINDOW_SAVE_AREA_SIZE
.data
.align 8
SYMBOL(physmem_base) ! copy of the physical memory base address
.quad 0
/*
* The fast_data_access_mmu_miss_data_hi label, the end_of_identity,
* kernel_8k_tlb_data_template and tlb_tag_access_context_mask variables
* are meant to stay together, aligned on a 32B boundary.
*/
.align 32
/*
* This label is used by the fast_data_access_MMU_miss trap handler.
*/
SYMBOL(fast_data_access_mmu_miss_data_hi)
/*
* This variable is used by the fast_data_access_MMU_miss trap handler.
* In runtime, it is modified to contain the address of the end of physical
* memory.
*/
SYMBOL(end_of_identity)
.quad -1
/*
* This variable is used by the fast_data_access_MMU_miss trap handler.
* In runtime, it is further modified to reflect the starting address of
* physical memory.
*/
SYMBOL(kernel_8k_tlb_data_template)
#ifdef CONFIG_VIRT_IDX_DCACHE
.quad ((1 << TTE_V_SHIFT) | (PAGESIZE_8K << TTE_SIZE_SHIFT) | TTE_CP | \
TTE_CV | TTE_P | TTE_W)
#else /* CONFIG_VIRT_IDX_DCACHE */
.quad ((1 << TTE_V_SHIFT) | (PAGESIZE_8K << TTE_SIZE_SHIFT) | TTE_CP | \
TTE_P | TTE_W)
#endif /* CONFIG_VIRT_IDX_DCACHE */
/*
* This variable is used by the fast_data_access_MMU_miss trap handler.
* It allows us to save one precious instruction slot of this handler.
*/
SYMBOL(tlb_tag_access_context_mask)
.quad TLB_TAG_ACCESS_CONTEXT_MASK