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132 | vana | 1 | # |
2071 | jermar | 2 | # Copyright (c) 2001-2004 Jakub Jermar |
132 | vana | 3 | # All rights reserved. |
4 | # |
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5 | # Redistribution and use in source and binary forms, with or without |
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6 | # modification, are permitted provided that the following conditions |
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7 | # are met: |
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8 | # |
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9 | # - Redistributions of source code must retain the above copyright |
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10 | # notice, this list of conditions and the following disclaimer. |
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11 | # - Redistributions in binary form must reproduce the above copyright |
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12 | # notice, this list of conditions and the following disclaimer in the |
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13 | # documentation and/or other materials provided with the distribution. |
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14 | # - The name of the author may not be used to endorse or promote products |
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15 | # derived from this software without specific prior written permission. |
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16 | # |
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17 | # THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR |
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18 | # IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES |
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19 | # OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. |
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20 | # IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, |
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21 | # INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT |
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22 | # NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
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23 | # DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
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24 | # THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
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25 | # (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF |
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26 | # THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
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27 | # |
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28 | |||
29 | ## very low and hardware-level functions |
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30 | |||
2613 | jermar | 31 | # Mask for interrupts 0 - 31 (bits 0 - 31) where 0 means that int has no error |
32 | # word and 1 means interrupt with error word |
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33 | #define ERROR_WORD_INTERRUPT_LIST 0x00027d00 |
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132 | vana | 34 | |
35 | .text |
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36 | |||
37 | .global paging_on |
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38 | .global enable_l_apic_in_msr |
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39 | .global interrupt_handlers |
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3043 | jermar | 40 | .global memsetb |
41 | .global memsetw |
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1288 | jermar | 42 | .global memcpy |
43 | .global memcpy_from_uspace |
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44 | .global memcpy_from_uspace_failover_address |
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45 | .global memcpy_to_uspace |
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46 | .global memcpy_to_uspace_failover_address |
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132 | vana | 47 | |
1288 | jermar | 48 | |
3043 | jermar | 49 | # Wrapper for generic memsetb |
50 | memsetb: |
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51 | jmp _memsetb |
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52 | |||
53 | # Wrapper for generic memsetw |
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54 | memsetw: |
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55 | jmp _memsetw |
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56 | |||
57 | |||
1288 | jermar | 58 | #define MEMCPY_DST 4 |
59 | #define MEMCPY_SRC 8 |
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60 | #define MEMCPY_SIZE 12 |
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61 | |||
62 | /** Copy memory to/from userspace. |
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63 | * |
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64 | * This is almost conventional memcpy(). |
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65 | * The difference is that there is a failover part |
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66 | * to where control is returned from a page fault |
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67 | * if the page fault occurs during copy_from_uspace() |
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68 | * or copy_to_uspace(). |
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69 | * |
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70 | * @param MEMCPY_DST(%esp) Destination address. |
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71 | * @param MEMCPY_SRC(%esp) Source address. |
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72 | * @param MEMCPY_SIZE(%esp) Size. |
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73 | * |
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3274 | jermar | 74 | * @return MEMCPY_DST(%esp) on success and 0 on failure. |
1288 | jermar | 75 | */ |
76 | memcpy: |
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77 | memcpy_from_uspace: |
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78 | memcpy_to_uspace: |
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2613 | jermar | 79 | movl %edi, %edx /* save %edi */ |
80 | movl %esi, %eax /* save %esi */ |
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1288 | jermar | 81 | |
82 | movl MEMCPY_SIZE(%esp), %ecx |
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2613 | jermar | 83 | shrl $2, %ecx /* size / 4 */ |
1288 | jermar | 84 | |
85 | movl MEMCPY_DST(%esp), %edi |
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86 | movl MEMCPY_SRC(%esp), %esi |
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87 | |||
2613 | jermar | 88 | rep movsl /* copy whole words */ |
1288 | jermar | 89 | |
90 | movl MEMCPY_SIZE(%esp), %ecx |
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2613 | jermar | 91 | andl $3, %ecx /* size % 4 */ |
1288 | jermar | 92 | jz 0f |
93 | |||
2613 | jermar | 94 | rep movsb /* copy the rest byte by byte */ |
1288 | jermar | 95 | |
96 | 0: |
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97 | movl %edx, %edi |
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98 | movl %eax, %esi |
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3274 | jermar | 99 | movl MEMCPY_DST(%esp), %eax /* MEMCPY_DST(%esp), success */ |
1288 | jermar | 100 | ret |
101 | |||
102 | /* |
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103 | * We got here from as_page_fault() after the memory operations |
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104 | * above had caused a page fault. |
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105 | */ |
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106 | memcpy_from_uspace_failover_address: |
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107 | memcpy_to_uspace_failover_address: |
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108 | movl %edx, %edi |
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109 | movl %eax, %esi |
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2613 | jermar | 110 | xorl %eax, %eax /* return 0, failure */ |
1288 | jermar | 111 | ret |
112 | |||
132 | vana | 113 | ## Turn paging on |
114 | # |
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115 | # Enable paging and write-back caching in CR0. |
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116 | # |
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117 | paging_on: |
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2613 | jermar | 118 | movl %cr0, %edx |
119 | orl $(1 << 31), %edx # paging on |
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120 | # clear Cache Disable and not Write Though |
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121 | andl $~((1 << 30) | (1 << 29)), %edx |
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316 | jermar | 122 | movl %edx,%cr0 |
132 | vana | 123 | jmp 0f |
124 | 0: |
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125 | ret |
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126 | |||
127 | |||
128 | ## Enable local APIC |
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129 | # |
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130 | # Enable local APIC in MSR. |
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131 | # |
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132 | enable_l_apic_in_msr: |
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133 | movl $0x1b, %ecx |
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134 | rdmsr |
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2613 | jermar | 135 | orl $(1 << 11), %eax |
136 | orl $(0xfee00000), %eax |
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132 | vana | 137 | wrmsr |
138 | ret |
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139 | |||
1100 | palkovsky | 140 | # Clear nested flag |
141 | # overwrites %ecx |
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142 | .macro CLEAR_NT_FLAG |
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143 | pushfl |
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144 | pop %ecx |
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2613 | jermar | 145 | and $0xffffbfff, %ecx |
1100 | palkovsky | 146 | push %ecx |
147 | popfl |
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148 | .endm |
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132 | vana | 149 | |
3492 | rimsky | 150 | /* |
151 | * The SYSENTER syscall mechanism can be used for syscalls with |
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152 | * four or fewer arguments. To pass these four arguments, we |
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153 | * use four registers: EDX, ECX, EBX, ESI. The syscall number |
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154 | * is passed in EAX. We use EDI to remember the return address |
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155 | * and EBP to remember the stack. The INT-based syscall mechanism |
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156 | * can actually handle six arguments plus the syscall number |
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157 | * entirely in registers. |
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158 | */ |
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159 | .global sysenter_handler |
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160 | sysenter_handler: |
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161 | pushl %ebp # remember user stack |
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162 | pushl %edi # remember return user address |
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163 | |||
164 | pushl %gs # remember TLS |
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165 | |||
166 | pushl %eax # syscall number |
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167 | subl $8, %esp # unused sixth and fifth argument |
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168 | pushl %esi # fourth argument |
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169 | pushl %ebx # third argument |
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170 | pushl %ecx # second argument |
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171 | pushl %edx # first argument |
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172 | |||
173 | movw $16, %ax |
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174 | movw %ax, %ds |
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175 | movw %ax, %es |
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176 | |||
177 | cld |
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178 | call syscall_handler |
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179 | addl $28, %esp # remove arguments from stack |
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180 | |||
181 | pop %gs # restore TLS |
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182 | |||
183 | pop %edx # prepare return EIP for SYSEXIT |
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184 | pop %ecx # prepare userspace ESP for SYSEXIT |
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185 | |||
186 | sysexit # return to userspace |
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187 | |||
188 | |||
132 | vana | 189 | ## Declare interrupt handlers |
190 | # |
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191 | # Declare interrupt handlers for n interrupt |
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192 | # vectors starting at vector i. |
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193 | # |
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194 | # The handlers setup data segment registers |
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576 | palkovsky | 195 | # and call exc_dispatch(). |
132 | vana | 196 | # |
1278 | palkovsky | 197 | #define INTERRUPT_ALIGN 64 |
132 | vana | 198 | .macro handler i n |
958 | jermar | 199 | |
2613 | jermar | 200 | .ifeq \i - 0x30 # Syscall handler |
201 | pushl %ds |
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202 | pushl %es |
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203 | pushl %fs |
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204 | pushl %gs |
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1100 | palkovsky | 205 | |
2613 | jermar | 206 | # |
207 | # Push syscall arguments onto the stack |
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208 | # |
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209 | # NOTE: The idea behind the order of arguments passed in registers is to |
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210 | # use all scratch registers first and preserved registers next. |
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211 | # An optimized libc syscall wrapper can make use of this setup. |
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212 | # |
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213 | pushl %eax |
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214 | pushl %ebp |
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215 | pushl %edi |
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216 | pushl %esi |
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217 | pushl %ebx |
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218 | pushl %ecx |
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219 | pushl %edx |
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1100 | palkovsky | 220 | |
221 | # we must fill the data segment registers |
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2613 | jermar | 222 | movw $16, %ax |
223 | movw %ax, %ds |
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224 | movw %ax, %es |
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1100 | palkovsky | 225 | |
2784 | jermar | 226 | cld |
1100 | palkovsky | 227 | sti |
2613 | jermar | 228 | # syscall_handler(edx, ecx, ebx, esi, edi, ebp, eax) |
229 | call syscall_handler |
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1100 | palkovsky | 230 | cli |
2613 | jermar | 231 | addl $28, %esp # clean-up of parameters |
1100 | palkovsky | 232 | |
2613 | jermar | 233 | popl %gs |
234 | popl %fs |
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235 | popl %es |
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236 | popl %ds |
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1100 | palkovsky | 237 | |
238 | CLEAR_NT_FLAG |
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239 | iret |
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240 | .else |
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1008 | jermar | 241 | /* |
1021 | jermar | 242 | * This macro distinguishes between two versions of ia32 exceptions. |
243 | * One version has error word and the other does not have it. |
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244 | * The latter version fakes the error word on the stack so that the |
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245 | * handlers and istate_t can be the same for both types. |
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1008 | jermar | 246 | */ |
2613 | jermar | 247 | .iflt \i - 32 |
1021 | jermar | 248 | .if (1 << \i) & ERROR_WORD_INTERRUPT_LIST |
1100 | palkovsky | 249 | /* |
250 | * With error word, do nothing |
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1021 | jermar | 251 | */ |
252 | .else |
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253 | /* |
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254 | * Version without error word, |
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255 | */ |
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256 | subl $4, %esp |
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257 | .endif |
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258 | .else |
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259 | /* |
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260 | * Version without error word, |
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261 | */ |
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262 | subl $4, %esp |
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1100 | palkovsky | 263 | .endif |
264 | |||
2613 | jermar | 265 | pushl %ds |
266 | pushl %es |
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267 | pushl %fs |
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268 | pushl %gs |
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132 | vana | 269 | |
1100 | palkovsky | 270 | #ifdef CONFIG_DEBUG_ALLREGS |
2613 | jermar | 271 | pushl %ebx |
272 | pushl %ebp |
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273 | pushl %edi |
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274 | pushl %esi |
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1100 | palkovsky | 275 | #else |
2613 | jermar | 276 | subl $16, %esp |
1100 | palkovsky | 277 | #endif |
2613 | jermar | 278 | pushl %edx |
279 | pushl %ecx |
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280 | pushl %eax |
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1100 | palkovsky | 281 | |
132 | vana | 282 | # we must fill the data segment registers |
2613 | jermar | 283 | movw $16, %ax |
284 | movw %ax, %ds |
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285 | movw %ax, %es |
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132 | vana | 286 | |
2784 | jermar | 287 | cld |
288 | |||
1100 | palkovsky | 289 | pushl %esp # *istate |
290 | pushl $(\i) # intnum |
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291 | call exc_dispatch # excdispatch(intnum, *istate) |
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2613 | jermar | 292 | addl $8, %esp # Clear arguments from stack |
132 | vana | 293 | |
1100 | palkovsky | 294 | CLEAR_NT_FLAG # Modifies %ecx |
295 | |||
2613 | jermar | 296 | popl %eax |
297 | popl %ecx |
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298 | popl %edx |
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1100 | palkovsky | 299 | #ifdef CONFIG_DEBUG_ALLREGS |
2613 | jermar | 300 | popl %esi |
301 | popl %edi |
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302 | popl %ebp |
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303 | popl %ebx |
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1100 | palkovsky | 304 | #else |
2613 | jermar | 305 | addl $16, %esp |
1100 | palkovsky | 306 | #endif |
307 | |||
2613 | jermar | 308 | popl %gs |
309 | popl %fs |
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310 | popl %es |
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311 | popl %ds |
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132 | vana | 312 | |
2613 | jermar | 313 | addl $4, %esp # Skip error word, no matter whether real or fake. |
316 | jermar | 314 | iret |
1100 | palkovsky | 315 | .endif |
132 | vana | 316 | |
1100 | palkovsky | 317 | .align INTERRUPT_ALIGN |
2613 | jermar | 318 | .if (\n- \i) - 1 |
319 | handler "(\i + 1)", \n |
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132 | vana | 320 | .endif |
321 | .endm |
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322 | |||
323 | # keep in sync with pm.h !!! |
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2613 | jermar | 324 | IDT_ITEMS = 64 |
1100 | palkovsky | 325 | .align INTERRUPT_ALIGN |
132 | vana | 326 | interrupt_handlers: |
327 | h_start: |
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1100 | palkovsky | 328 | handler 0 IDT_ITEMS |
132 | vana | 329 | h_end: |
330 | |||
331 | .data |
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332 | .global interrupt_handler_size |
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333 | |||
2613 | jermar | 334 | interrupt_handler_size: .long (h_end - h_start) / IDT_ITEMS |