/* SPDX-License-Identifier: GPL-2.0 */ /* * ld script for the x86 kernel * * Historic 32-bit version written by Martin Mares * * Modernisation, unification and other changes and fixes: * Copyright (C) 2007-2009 Sam Ravnborg * * * Don't define absolute symbols until and unless you know that symbol * value is should remain constant even if kernel image is relocated * at run time. Absolute symbols are not relocated. If symbol value should * change if kernel is relocated, make the symbol section relative and * put it inside the section definition. */ #ifdef CONFIG_X86_32 #define LOAD_OFFSET __PAGE_OFFSET #else #define LOAD_OFFSET __START_KERNEL_map #endif #define RUNTIME_DISCARD_EXIT #define EMITS_PT_NOTE #define RO_EXCEPTION_TABLE_ALIGN 16 #include #include #include #include #include #include #include #undef i386 /* in case the preprocessor is a 32bit one */ OUTPUT_FORMAT(CONFIG_OUTPUT_FORMAT) #ifdef CONFIG_X86_32 OUTPUT_ARCH(i386) ENTRY(phys_startup_32) #else OUTPUT_ARCH(i386:x86-64) ENTRY(phys_startup_64) #endif jiffies = jiffies_64; #if defined(CONFIG_X86_64) /* * On 64-bit, align RODATA to 2MB so we retain large page mappings for * boundaries spanning kernel text, rodata and data sections. * * However, kernel identity mappings will have different RWX permissions * to the pages mapping to text and to the pages padding (which are freed) the * text section. Hence kernel identity mappings will be broken to smaller * pages. For 64-bit, kernel text and kernel identity mappings are different, * so we can enable protection checks as well as retain 2MB large page * mappings for kernel text. */ #define X86_ALIGN_RODATA_BEGIN . = ALIGN(HPAGE_SIZE); #define X86_ALIGN_RODATA_END \ . = ALIGN(HPAGE_SIZE); \ __end_rodata_hpage_align = .; \ __end_rodata_aligned = .; #define ALIGN_ENTRY_TEXT_BEGIN . = ALIGN(PMD_SIZE); #define ALIGN_ENTRY_TEXT_END . = ALIGN(PMD_SIZE); /* * This section contains data which will be mapped as decrypted. Memory * encryption operates on a page basis. Make this section PMD-aligned * to avoid splitting the pages while mapping the section early. * * Note: We use a separate section so that only this section gets * decrypted to avoid exposing more than we wish. */ #define BSS_DECRYPTED \ . = ALIGN(PMD_SIZE); \ __start_bss_decrypted = .; \ *(.bss..decrypted); \ . = ALIGN(PAGE_SIZE); \ __start_bss_decrypted_unused = .; \ . = ALIGN(PMD_SIZE); \ __end_bss_decrypted = .; \ #else #define X86_ALIGN_RODATA_BEGIN #define X86_ALIGN_RODATA_END \ . = ALIGN(PAGE_SIZE); \ __end_rodata_aligned = .; #define ALIGN_ENTRY_TEXT_BEGIN #define ALIGN_ENTRY_TEXT_END #define BSS_DECRYPTED #endif PHDRS { text PT_LOAD FLAGS(5); /* R_E */ data PT_LOAD FLAGS(6); /* RW_ */ #ifdef CONFIG_X86_64 #ifdef CONFIG_SMP percpu PT_LOAD FLAGS(6); /* RW_ */ #endif init PT_LOAD FLAGS(7); /* RWE */ #endif note PT_NOTE FLAGS(0); /* ___ */ } SECTIONS { #ifdef CONFIG_X86_32 . = LOAD_OFFSET + LOAD_PHYSICAL_ADDR; phys_startup_32 = ABSOLUTE(startup_32 - LOAD_OFFSET); #else . = __START_KERNEL; phys_startup_64 = ABSOLUTE(startup_64 - LOAD_OFFSET); #endif /* Text and read-only data */ .text : AT(ADDR(.text) - LOAD_OFFSET) { _text = .; _stext = .; /* bootstrapping code */ HEAD_TEXT TEXT_TEXT SCHED_TEXT CPUIDLE_TEXT LOCK_TEXT KPROBES_TEXT ALIGN_ENTRY_TEXT_BEGIN #ifdef CONFIG_CPU_SRSO *(.text..__x86.rethunk_untrain) #endif ENTRY_TEXT #ifdef CONFIG_CPU_SRSO /* * See the comment above srso_alias_untrain_ret()'s * definition. */ . = srso_alias_untrain_ret | (1 << 2) | (1 << 8) | (1 << 14) | (1 << 20); *(.text..__x86.rethunk_safe) #endif ALIGN_ENTRY_TEXT_END SOFTIRQENTRY_TEXT STATIC_CALL_TEXT *(.fixup) *(.gnu.warning) #ifdef CONFIG_RETPOLINE __indirect_thunk_start = .; *(.text..__x86.indirect_thunk) *(.text..__x86.return_thunk) __indirect_thunk_end = .; #endif } :text =0xcccc /* End of text section, which should occupy whole number of pages */ _etext = .; . = ALIGN(PAGE_SIZE); X86_ALIGN_RODATA_BEGIN RO_DATA(PAGE_SIZE) X86_ALIGN_RODATA_END /* Data */ .data : AT(ADDR(.data) - LOAD_OFFSET) { /* Start of data section */ _sdata = .; /* init_task */ INIT_TASK_DATA(THREAD_SIZE) #ifdef CONFIG_X86_32 /* 32 bit has nosave before _edata */ NOSAVE_DATA #endif PAGE_ALIGNED_DATA(PAGE_SIZE) CACHELINE_ALIGNED_DATA(L1_CACHE_BYTES) DATA_DATA CONSTRUCTORS /* rarely changed data like cpu maps */ READ_MOSTLY_DATA(INTERNODE_CACHE_BYTES) /* End of data section */ _edata = .; } :data BUG_TABLE ORC_UNWIND_TABLE . = ALIGN(PAGE_SIZE); __vvar_page = .; .vvar : AT(ADDR(.vvar) - LOAD_OFFSET) { /* work around gold bug 13023 */ __vvar_beginning_hack = .; /* Place all vvars at the offsets in asm/vvar.h. */ #define EMIT_VVAR(name, offset) \ . = __vvar_beginning_hack + offset; \ *(.vvar_ ## name) #include #undef EMIT_VVAR /* * Pad the rest of the page with zeros. Otherwise the loader * can leave garbage here. */ . = __vvar_beginning_hack + PAGE_SIZE; } :data . = ALIGN(__vvar_page + PAGE_SIZE, PAGE_SIZE); /* Init code and data - will be freed after init */ . = ALIGN(PAGE_SIZE); .init.begin : AT(ADDR(.init.begin) - LOAD_OFFSET) { __init_begin = .; /* paired with __init_end */ } #if defined(CONFIG_X86_64) && defined(CONFIG_SMP) /* * percpu offsets are zero-based on SMP. PERCPU_VADDR() changes the * output PHDR, so the next output section - .init.text - should * start another segment - init. */ PERCPU_VADDR(INTERNODE_CACHE_BYTES, 0, :percpu) ASSERT(SIZEOF(.data..percpu) < CONFIG_PHYSICAL_START, "per-CPU data too large - increase CONFIG_PHYSICAL_START") #endif INIT_TEXT_SECTION(PAGE_SIZE) #ifdef CONFIG_X86_64 :init #endif /* * Section for code used exclusively before alternatives are run. All * references to such code must be patched out by alternatives, normally * by using X86_FEATURE_ALWAYS CPU feature bit. * * See static_cpu_has() for an example. */ .altinstr_aux : AT(ADDR(.altinstr_aux) - LOAD_OFFSET) { *(.altinstr_aux) } INIT_DATA_SECTION(16) .x86_cpu_dev.init : AT(ADDR(.x86_cpu_dev.init) - LOAD_OFFSET) { __x86_cpu_dev_start = .; *(.x86_cpu_dev.init) __x86_cpu_dev_end = .; } #ifdef CONFIG_X86_INTEL_MID .x86_intel_mid_dev.init : AT(ADDR(.x86_intel_mid_dev.init) - \ LOAD_OFFSET) { __x86_intel_mid_dev_start = .; *(.x86_intel_mid_dev.init) __x86_intel_mid_dev_end = .; } #endif /* * start address and size of operations which during runtime * can be patched with virtualization friendly instructions or * baremetal native ones. Think page table operations. * Details in paravirt_types.h */ . = ALIGN(8); .parainstructions : AT(ADDR(.parainstructions) - LOAD_OFFSET) { __parainstructions = .; *(.parainstructions) __parainstructions_end = .; } #ifdef CONFIG_RETPOLINE /* * List of instructions that call/jmp/jcc to retpoline thunks * __x86_indirect_thunk_*(). These instructions can be patched along * with alternatives, after which the section can be freed. */ . = ALIGN(8); .retpoline_sites : AT(ADDR(.retpoline_sites) - LOAD_OFFSET) { __retpoline_sites = .; *(.retpoline_sites) __retpoline_sites_end = .; } . = ALIGN(8); .return_sites : AT(ADDR(.return_sites) - LOAD_OFFSET) { __return_sites = .; *(.return_sites) __return_sites_end = .; } #endif /* * struct alt_inst entries. From the header (alternative.h): * "Alternative instructions for different CPU types or capabilities" * Think locking instructions on spinlocks. */ . = ALIGN(8); .altinstructions : AT(ADDR(.altinstructions) - LOAD_OFFSET) { __alt_instructions = .; *(.altinstructions) __alt_instructions_end = .; } /* * And here are the replacement instructions. The linker sticks * them as binary blobs. The .altinstructions has enough data to * get the address and the length of them to patch the kernel safely. */ .altinstr_replacement : AT(ADDR(.altinstr_replacement) - LOAD_OFFSET) { *(.altinstr_replacement) } /* * struct iommu_table_entry entries are injected in this section. * It is an array of IOMMUs which during run time gets sorted depending * on its dependency order. After rootfs_initcall is complete * this section can be safely removed. */ .iommu_table : AT(ADDR(.iommu_table) - LOAD_OFFSET) { __iommu_table = .; *(.iommu_table) __iommu_table_end = .; } . = ALIGN(8); .apicdrivers : AT(ADDR(.apicdrivers) - LOAD_OFFSET) { __apicdrivers = .; *(.apicdrivers); __apicdrivers_end = .; } . = ALIGN(8); /* * .exit.text is discarded at runtime, not link time, to deal with * references from .altinstructions */ .exit.text : AT(ADDR(.exit.text) - LOAD_OFFSET) { EXIT_TEXT } .exit.data : AT(ADDR(.exit.data) - LOAD_OFFSET) { EXIT_DATA } #if !defined(CONFIG_X86_64) || !defined(CONFIG_SMP) PERCPU_SECTION(INTERNODE_CACHE_BYTES) #endif . = ALIGN(PAGE_SIZE); /* freed after init ends here */ .init.end : AT(ADDR(.init.end) - LOAD_OFFSET) { __init_end = .; } /* * smp_locks might be freed after init * start/end must be page aligned */ . = ALIGN(PAGE_SIZE); .smp_locks : AT(ADDR(.smp_locks) - LOAD_OFFSET) { __smp_locks = .; *(.smp_locks) . = ALIGN(PAGE_SIZE); __smp_locks_end = .; } #ifdef CONFIG_X86_64 .data_nosave : AT(ADDR(.data_nosave) - LOAD_OFFSET) { NOSAVE_DATA } #endif /* BSS */ . = ALIGN(PAGE_SIZE); .bss : AT(ADDR(.bss) - LOAD_OFFSET) { __bss_start = .; *(.bss..page_aligned) . = ALIGN(PAGE_SIZE); *(BSS_MAIN) BSS_DECRYPTED . = ALIGN(PAGE_SIZE); __bss_stop = .; } /* * The memory occupied from _text to here, __end_of_kernel_reserve, is * automatically reserved in setup_arch(). Anything after here must be * explicitly reserved using memblock_reserve() or it will be discarded * and treated as available memory. */ __end_of_kernel_reserve = .; . = ALIGN(PAGE_SIZE); .brk : AT(ADDR(.brk) - LOAD_OFFSET) { __brk_base = .; . += 64 * 1024; /* 64k alignment slop space */ *(.bss..brk) /* areas brk users have reserved */ __brk_limit = .; } . = ALIGN(PAGE_SIZE); /* keep VO_INIT_SIZE page aligned */ _end = .; #ifdef CONFIG_AMD_MEM_ENCRYPT /* * Early scratch/workarea section: Lives outside of the kernel proper * (_text - _end). * * Resides after _end because even though the .brk section is after * __end_of_kernel_reserve, the .brk section is later reserved as a * part of the kernel. Since it is located after __end_of_kernel_reserve * it will be discarded and become part of the available memory. As * such, it can only be used by very early boot code and must not be * needed afterwards. * * Currently used by SME for performing in-place encryption of the * kernel during boot. Resides on a 2MB boundary to simplify the * pagetable setup used for SME in-place encryption. */ . = ALIGN(HPAGE_SIZE); .init.scratch : AT(ADDR(.init.scratch) - LOAD_OFFSET) { __init_scratch_begin = .; *(.init.scratch) . = ALIGN(HPAGE_SIZE); __init_scratch_end = .; } #endif STABS_DEBUG DWARF_DEBUG ELF_DETAILS DISCARDS /* * Make sure that the .got.plt is either completely empty or it * contains only the lazy dispatch entries. */ .got.plt (INFO) : { *(.got.plt) } ASSERT(SIZEOF(.got.plt) == 0 || #ifdef CONFIG_X86_64 SIZEOF(.got.plt) == 0x18, #else SIZEOF(.got.plt) == 0xc, #endif "Unexpected GOT/PLT entries detected!") /* * Sections that should stay zero sized, which is safer to * explicitly check instead of blindly discarding. */ .got : { *(.got) *(.igot.*) } ASSERT(SIZEOF(.got) == 0, "Unexpected GOT entries detected!") .plt : { *(.plt) *(.plt.*) *(.iplt) } ASSERT(SIZEOF(.plt) == 0, "Unexpected run-time procedure linkages detected!") .rel.dyn : { *(.rel.*) *(.rel_*) } ASSERT(SIZEOF(.rel.dyn) == 0, "Unexpected run-time relocations (.rel) detected!") .rela.dyn : { *(.rela.*) *(.rela_*) } ASSERT(SIZEOF(.rela.dyn) == 0, "Unexpected run-time relocations (.rela) detected!") } /* * The ASSERT() sink to . is intentional, for binutils 2.14 compatibility: */ . = ASSERT((_end - LOAD_OFFSET <= KERNEL_IMAGE_SIZE), "kernel image bigger than KERNEL_IMAGE_SIZE"); #ifdef CONFIG_X86_64 /* * Per-cpu symbols which need to be offset from __per_cpu_load * for the boot processor. */ #define INIT_PER_CPU(x) init_per_cpu__##x = ABSOLUTE(x) + __per_cpu_load INIT_PER_CPU(gdt_page); INIT_PER_CPU(fixed_percpu_data); INIT_PER_CPU(irq_stack_backing_store); #ifdef CONFIG_SMP . = ASSERT((fixed_percpu_data == 0), "fixed_percpu_data is not at start of per-cpu area"); #endif #ifdef CONFIG_RETHUNK . = ASSERT((retbleed_return_thunk & 0x3f) == 0, "retbleed_return_thunk not cacheline-aligned"); . = ASSERT((srso_safe_ret & 0x3f) == 0, "srso_safe_ret not cacheline-aligned"); #endif #ifdef CONFIG_CPU_SRSO /* * GNU ld cannot do XOR until 2.41. * https://sourceware.org/git/?p=binutils-gdb.git;a=commit;h=f6f78318fca803c4907fb8d7f6ded8295f1947b1 * * LLVM lld cannot do XOR until lld-17. * https://github.com/llvm/llvm-project/commit/fae96104d4378166cbe5c875ef8ed808a356f3fb * * Instead do: (A | B) - (A & B) in order to compute the XOR * of the two function addresses: */ . = ASSERT(((ABSOLUTE(srso_alias_untrain_ret) | srso_alias_safe_ret) - (ABSOLUTE(srso_alias_untrain_ret) & srso_alias_safe_ret)) == ((1 << 2) | (1 << 8) | (1 << 14) | (1 << 20)), "SRSO function pair won't alias"); #endif #endif /* CONFIG_X86_64 */ #ifdef CONFIG_KEXEC_CORE #include . = ASSERT(kexec_control_code_size <= KEXEC_CONTROL_CODE_MAX_SIZE, "kexec control code size is too big"); #endif