source: trunk/hal/tsar_mips32/hal_kentry.S @ 17

/*
 * hal_kentry.S - exception/interrupt/syscall kernel entry point for MIPS32
 * 
 * AUthors   Ghassan Almaless (2007,2008,2009,2010,2011,2012)
 *           Mohamed Lamine Karaoui (2015)
 *           Alain Greiner (2017)
 *
 * Copyright (c) UPMC Sorbonne Universites
 * 
 * This file is part of ALMOS-MKH.
 *
 * ALMOS-MKH is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License as published by
 * the Free Software Foundation; version 2.0 of the License.
 *
 * ALMOS-MKH is distributed in the hope that it will be useful, but
 * WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with ALMOS-MKH; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
 */

#include <mips32_uzone.h>

#---------------------------------------------------------------------------------
# This code is the unique kernel entry point in case of exception, interrupt,
# or syscall for the TSAR_MIPS32 architecture.  
#
# - If the core is in user mode:
#   . we desactivate the MMU.
#   . we save the context in the uzone of the calling thread descriptor.
#   . we increment the cores_in_kernel variable.
#   . we call the relevant exception/interrupt/syscall handler
#
# - If the core is already in kernel mode: 
#   . we save the context in the kernel stack
#   . we call the relevant exception/interrupt/syscall handler
#
# - In both cases, when the handler returns:
#   . we restore the context
#   . we reactivate the MMU ??? 
#---------------------------------------------------------------------------------

        .section   .kentry,"ax",@progbits
        .extern    cpu_do_interrupt
        .extern    cpu_do_exception
        .extern    cpu_do_syscall
        .extern    cpu_kentry
        .extern    cpu_kexit
        .org       0x180
        .ent       kentry
        .global    kentry
        .global    kentry_load
        .set       noat
        .set       noreorder

#define SAVE_SIZE      CPU_REGS_NR*4
#define LID_WIDTH      2
#define CXY_WIDTH      8
#define CXY_MASK       0xFF
#define MMU_MODE_MASK  0xF
#define GID_MASK       0x3FF    
#define LID_MASK       0x3      

#---------------------------------------------------------------------------------
# Kernel Entry point
#---------------------------------------------------------------------------------

kentry:
        mfc0    $26,    $12                 # read SR to test user/kernel mode
        andi    $26,    $26,  0x10          # User Mode bitmask
        beq     $26,    $0,       kernel_mode
        ori     $26,    $0,       0x3               # $26 <= MMU OFF value
        
#---------------------------------------------------------------------------------------        
# this code is executed when the core is in user mode:
# - we use the uzone defined in user thread descriptor. 
# - we set the MMU off, and save the CP2_MODE register to uzone.
# - we save the user thread stack pointer to uzone and load the kernel stack pointer
# - we store the uzone pointer in $27

user_mode:
        mtc2    $26,    $1                              # set MMU OFF
        nop

        mfc0    $26,    $4,   2             # $26 <= thread pointer 
        lw      $26,    0($26)              # $26 <= uzone pointer

        sw      $29,    (UZ_SP*4)($26)      # save user stack to uzone
        lw      $29,    (UZ_KSP*4)($26)     # load kernel stack from uzone

        ori     $27,    $0,       0xF           # MMU old value: assumed ON
        sw      $27,    (UZ_MODE*4)($26)    # save MMU MODE to uzone

        j           unified_mode
        or      $27,    $0,       $26           # $27 <= uzone

#---------------------------------------------------------------------------------------        
# this code is executed when the core is in kernel mode:
# - we use an uzone allocated in kernel stack.
# - we set the MMU off, set the MMU data_paddr extension to local_cxy,
#   and save the CP2_MODE and CP2_DEXT to uzone.
# - we save the kernel stack pointer to uzone and load the new kernel stack pointer
# - we store the uzone pointer in $27

kernel_mode:
        mfc2    $26,    $24
        andi    $26,    $26,  CXY_MASK      # $26 <= CP2_DEXT 

        mfc0    $27,    $15,  1
        andi    $27,    $27,  GID_MASK      # $27 <= core_gid (4/4/2 format)    

        srl         $27,    $27,  LID_WIDTH         # $27 <= local_cxy
        mtc2    $27,    $24                             # set local_cxy to CP2_DEXT

    # use $26 to save both CP2_MODE (4 bits) and CP2_DEXT (8 bits) values

        mfc2    $27,    $1
        andi    $27,    $27,  MMU_MODE_MASK     # $27 <= CP2_MODE
        sll         $27,    $27,  CXY_WIDTH         # $27 <= 0x00000M00
        or          $26,    $26,  $27           # $26 <= 0x00000MXY 

        ori     $27,    $0,       0x3
        mtc2    $27,    $1                              # set MMU OFF

        # save old SP, CP2_MODE and CP2_DEXT in uzone allocated in kernel stack

        addiu   $27,    $29,  -(SAVE_SIZE)      # allocate an uzone in stack (use $27 as KSP)
        sw      $29,    (UZ_SP*4)($27)      # save old KSP in this uzone

        srl     $29,    $26,  CXY_WIDTH 
        sw      $29,    (UZ_MODE*4)($27)    # save CP2_MODE in this uzone

        andi    $26,    $26,  CXY_MASK  
        sw      $26,    (UZ_DEXT*4)($27)    # save CP2_DEXT in this uzone 

        or      $29,    $27,    $0          # load new kernel stack pointer

#-------------------------------------------------------------------------------------- 
# this code is executed in both modes, with the two following assumptions:
# - $27 contains the pointer on uzone to save the cpu registers
# - $29 contains the kernel stack pointer

unified_mode:   
        sw      $1,         (UZ_AT*4)($27)
        sw      $2,     (UZ_V0*4)($27)
        sw      $3,     (UZ_V1*4)($27)
        sw      $4,     (UZ_A0*4)($27)
        sw      $5,     (UZ_A1*4)($27)
        sw      $6,     (UZ_A2*4)($27)
        sw      $7,     (UZ_A3*4)($27)
        sw      $8,     (UZ_T0*4)($27)
        sw      $9,     (UZ_T1*4)($27)
        sw      $10,    (UZ_T2*4)($27)
        sw      $11,    (UZ_T3*4)($27)
        sw      $12,    (UZ_T4*4)($27)
        sw      $13,    (UZ_T5*4)($27)
        sw      $14,    (UZ_T6*4)($27)
        sw      $15,    (UZ_T7*4)($27)
        sw      $16,    (UZ_S0*4)($27)
        sw      $17,    (UZ_S1*4)($27)
        sw          $18,        (UZ_S2*4)($27)
        sw          $19,        (UZ_S3*4)($27)
        sw          $20,        (UZ_S4*4)($27)
        sw          $21,        (UZ_S5*4)($27)
        sw          $22,        (UZ_S6*4)($27)
        sw          $23,        (UZ_S7*4)($27)
        sw      $24,    (UZ_T8*4)($27)
        sw      $25,    (UZ_T9*4)($27)
        sw          $28,        (UZ_GP*4)($27)
        sw          $30,        (UZ_S8*4)($27)
        sw          $31,        (UZ_RA*4)($27)

        mfc0    $16,    $14
        sw      $16,    (UZ_EPC*4)($27)     # Save EPC
        mflo    $14
        sw      $14,    (UZ_LO*4)($27)      # save LO
        mfhi    $15 
        sw      $15,    (UZ_HI*4)($27)          # save HI
        mfc0    $18,    $12 
        sw          $18,        (UZ_SR*4)($27)          # Save SR
        mfc0    $17,    $13
        sw      $17,    (UZ_CR*4)($27)          # Save CR

        srl         $3,     $18,  5                 # put SR in kernel mode, IRQ disabled, clear exl
        sll     $3,         $3,   5     
        mtc0    $3,         $12                         # Set new SR

        andi    $1,     $17,  0x3F          # $1 <= XCODE (from CR)

        # signal that core enters kernel
        jal         cluster_core_kernel_enter
    nop

#---------------------------------------------------------------------------------------
# Depending on XCODE (in $1) , call the apropriate handler. The three called
# functions take the same two arguments: thread pointer and uzone pointer.

        mfc0    $4,     $4,   2             # $4 <= thread pointer (first arg)
        or          $5,     $0,   $27               # $5 <= uzone pointer (second arg)
        or          $19,    $0,   $27           # $19 <= &uzone (for kentry_exit)

        ori         $8,     $0,   0x20          # $8 <= cause syscall
    beq     $8,     $1,   cause_sys
    nop
        beq     $1,     $0,       cause_int
    nop

cause_excp:
        la      $1,         hal_do_exception
        jalr    $1                              # call exception handler
        addiu   $29,    $29,  -8                # hal_do_exception has 2 args
        addiu   $29,    $29,  8
        j       kentry_exit                 # jump to kentry_exit
    nop

cause_sys:
        la          $1,         hal_do_syscall
        jalr    $1                          # call syscall handler                 
        addiu   $29,    $29,  -8            # hal_do_syscall has 2 args
        addiu   $29,    $29,  8
        j           kentry_exit                 # jump to kentry_exit
        or          $19,        $0,   $2
        
cause_int:
        la          $1,     hal_do_interrupt
        jalr    $1                          # call interrupt handler
        addiu   $29,    $29,  -8            # hal_do_interrupt has 2 args
        addiu   $29,    $29,  8

# -----------------------------------------------------------------------------------
# Kentry exit
# -----------------------------------------------------------------------------------
kentry_exit:

        # signal that core exit kernel
    jal     cluster_core_kernel_exit

        # restore context from uzone
        or          $27,    $0, $19             # $27 <= &uzone

        lw          $29,        (UZ_SP*4)($27)          # restore SP from uzone
        lw          $16,        (UZ_EPC*4)($27)        
        mtc0    $16,    $14                             # restore EPC from uzone
        lw          $16,    (UZ_HI*4)($27)
        mthi    $16                                         # restore HI from uzone
        lw          $16,    (UZ_LO*4)($27)
        mtlo    $16                                         # restore LO from uzone

        lw          $17,        (UZ_SR*4)($27)          # get saved SR value from uzone
        andi    $17,    $17,    0x1F        # keep only the 5 LSB bits
        mfc0    $26,    $12                             # get current SR value from CP0
        or          $26,    $26,        $17         # merge the two values
        mtc0    $26,    $12                             # setup new SR to CP0

        lw          $1,     (UZ_AT*4)($27)              
        lw          $2,     (UZ_V0*4)($27)
        lw          $3,     (UZ_V1*4)($27)
        lw          $4,     (UZ_A0*4)($27)
        lw          $5,     (UZ_A1*4)($27)
        lw          $6,     (UZ_A2*4)($27)
        lw          $7,     (UZ_A3*4)($27)
        lw          $8,     (UZ_T0*4)($27)
        lw          $9,     (UZ_T1*4)($27)
        lw          $10,    (UZ_T2*4)($27)
        lw          $11,    (UZ_T3*4)($27)
        lw          $12,    (UZ_T4*4)($27)
        lw          $13,    (UZ_T5*4)($27)
        lw          $14,    (UZ_T6*4)($27)
        lw          $15,    (UZ_T7*4)($27)
        lw          $16,    (UZ_S0*4)($27)
        lw          $17,    (UZ_S1*4)($27)
        lw          $18,        (UZ_S2*4)($27)
        lw          $19,    (UZ_S3*4)($27)
        lw          $20,        (UZ_S4*4)($27)
        lw          $21,        (UZ_S5*4)($27)
        lw          $22,        (UZ_S6*4)($27)
        lw          $23,        (UZ_S7*4)($27)
        lw          $24,    (UZ_T8*4)($27)
        lw          $25,    (UZ_T9*4)($27)      
        lw          $28,        (UZ_GP*4)($27)
        lw          $30,        (UZ_S8*4)($27)
        lw          $31,        (UZ_RA*4)($27)


        lw          $26,    (UZ_DEXT*4)($27)
        mtc2    $26,    $24                             # restore CP2_DEXT from uzone

    #TODO: optimize
        lw          $26,    (UZ_MODE*4)($27)    # get saved CP2_MODE from uzone
        andi    $26,    $26,    0xc         # keep only the TLBs controling bits
        beq     $26,    $0,         out_mmu_3   # both MSB are 0 (the first two LSB are always set)
        andi    $26,    $26,    0x8
        beq     $26,    $0,         out_mmu_7   # first MSB is 0 (bit 2 is set)

# Possible value for MMU_MODE
# In kernel mode : 0x7/0x3
# In user mode   : 0xF

# DP_EXT can either be local or remote
# Once these register set we can no longuer 
# access global data

out_mmu_F:
        ori         $26,        $0,        0xF
        mtc2    $26,    $1                              # CP2_MODE <= 0xF
        j           out_kentry
        nop

out_mmu_7:
        ori         $26,    $0,    0x7  
        mtc2    $26,    $1                              # CP2_MODE <= 0x7
        j       out_kentry
        nop

out_mmu_3:
        ori     $26,    $0,        0x3
        mtc2    $26,    $1                              # CP2_MODE <= 0x3

out_kentry:
        nop
    eret

    .end kentry
    .set reorder
    .set at

        .ent kentry_load
kentry_load:
        # theses nops are required to load the eret instruction
        # while we are in virtual mode (processor pipeline) ?
        mtc2     $26,    $1            # set MMU MODE
        nop                     
        nop
    eret
    .end kentry_load

#-------------------------------------------------------------------------------