@@ -12,6 +12,7 @@ that goes into great technical depth about the BPF Architecture.
.. toctree::
:maxdepth: 1
+ intro
instruction-set
verifier
libbpf/index
@@ -3,246 +3,21 @@
eBPF Instruction Set
====================
-eBPF is designed to be JITed with one to one mapping, which can also open up
-the possibility for GCC/LLVM compilers to generate optimized eBPF code through
-an eBPF backend that performs almost as fast as natively compiled code.
-
-Some core changes of the eBPF format from classic BPF:
-
-- Number of registers increase from 2 to 10:
-
- The old format had two registers A and X, and a hidden frame pointer. The
- new layout extends this to be 10 internal registers and a read-only frame
- pointer. Since 64-bit CPUs are passing arguments to functions via registers
- the number of args from eBPF program to in-kernel function is restricted
- to 5 and one register is used to accept return value from an in-kernel
- function. Natively, x86_64 passes first 6 arguments in registers, aarch64/
- sparcv9/mips64 have 7 - 8 registers for arguments; x86_64 has 6 callee saved
- registers, and aarch64/sparcv9/mips64 have 11 or more callee saved registers.
-
- Therefore, eBPF calling convention is defined as:
-
- * R0 - return value from in-kernel function, and exit value for eBPF program
- * R1 - R5 - arguments from eBPF program to in-kernel function
- * R6 - R9 - callee saved registers that in-kernel function will preserve
- * R10 - read-only frame pointer to access stack
-
- Thus, all eBPF registers map one to one to HW registers on x86_64, aarch64,
- etc, and eBPF calling convention maps directly to ABIs used by the kernel on
- 64-bit architectures.
-
- On 32-bit architectures JIT may map programs that use only 32-bit arithmetic
- and may let more complex programs to be interpreted.
-
- R0 - R5 are scratch registers and eBPF program needs spill/fill them if
- necessary across calls. Note that there is only one eBPF program (== one
- eBPF main routine) and it cannot call other eBPF functions, it can only
- call predefined in-kernel functions, though.
-
-- Register width increases from 32-bit to 64-bit:
-
- Still, the semantics of the original 32-bit ALU operations are preserved
- via 32-bit subregisters. All eBPF registers are 64-bit with 32-bit lower
- subregisters that zero-extend into 64-bit if they are being written to.
- That behavior maps directly to x86_64 and arm64 subregister definition, but
- makes other JITs more difficult.
-
- 32-bit architectures run 64-bit eBPF programs via interpreter.
- Their JITs may convert BPF programs that only use 32-bit subregisters into
- native instruction set and let the rest being interpreted.
-
- Operation is 64-bit, because on 64-bit architectures, pointers are also
- 64-bit wide, and we want to pass 64-bit values in/out of kernel functions,
- so 32-bit eBPF registers would otherwise require to define register-pair
- ABI, thus, there won't be able to use a direct eBPF register to HW register
- mapping and JIT would need to do combine/split/move operations for every
- register in and out of the function, which is complex, bug prone and slow.
- Another reason is the use of atomic 64-bit counters.
-
-- Conditional jt/jf targets replaced with jt/fall-through:
-
- While the original design has constructs such as ``if (cond) jump_true;
- else jump_false;``, they are being replaced into alternative constructs like
- ``if (cond) jump_true; /* else fall-through */``.
-
-- Introduces bpf_call insn and register passing convention for zero overhead
- calls from/to other kernel functions:
-
- Before an in-kernel function call, the eBPF program needs to
- place function arguments into R1 to R5 registers to satisfy calling
- convention, then the interpreter will take them from registers and pass
- to in-kernel function. If R1 - R5 registers are mapped to CPU registers
- that are used for argument passing on given architecture, the JIT compiler
- doesn't need to emit extra moves. Function arguments will be in the correct
- registers and BPF_CALL instruction will be JITed as single 'call' HW
- instruction. This calling convention was picked to cover common call
- situations without performance penalty.
-
- After an in-kernel function call, R1 - R5 are reset to unreadable and R0 has
- a return value of the function. Since R6 - R9 are callee saved, their state
- is preserved across the call.
-
- For example, consider three C functions::
-
- u64 f1() { return (*_f2)(1); }
- u64 f2(u64 a) { return f3(a + 1, a); }
- u64 f3(u64 a, u64 b) { return a - b; }
-
- GCC can compile f1, f3 into x86_64::
-
- f1:
- movl $1, %edi
- movq _f2(%rip), %rax
- jmp *%rax
- f3:
- movq %rdi, %rax
- subq %rsi, %rax
- ret
-
- Function f2 in eBPF may look like::
-
- f2:
- bpf_mov R2, R1
- bpf_add R1, 1
- bpf_call f3
- bpf_exit
-
- If f2 is JITed and the pointer stored to ``_f2``. The calls f1 -> f2 -> f3 and
- returns will be seamless. Without JIT, __bpf_prog_run() interpreter needs to
- be used to call into f2.
-
- For practical reasons all eBPF programs have only one argument 'ctx' which is
- already placed into R1 (e.g. on __bpf_prog_run() startup) and the programs
- can call kernel functions with up to 5 arguments. Calls with 6 or more arguments
- are currently not supported, but these restrictions can be lifted if necessary
- in the future.
-
- On 64-bit architectures all register map to HW registers one to one. For
- example, x86_64 JIT compiler can map them as ...
-
- ::
-
- R0 - rax
- R1 - rdi
- R2 - rsi
- R3 - rdx
- R4 - rcx
- R5 - r8
- R6 - rbx
- R7 - r13
- R8 - r14
- R9 - r15
- R10 - rbp
-
- ... since x86_64 ABI mandates rdi, rsi, rdx, rcx, r8, r9 for argument passing
- and rbx, r12 - r15 are callee saved.
-
- Then the following eBPF pseudo-program::
-
- bpf_mov R6, R1 /* save ctx */
- bpf_mov R2, 2
- bpf_mov R3, 3
- bpf_mov R4, 4
- bpf_mov R5, 5
- bpf_call foo
- bpf_mov R7, R0 /* save foo() return value */
- bpf_mov R1, R6 /* restore ctx for next call */
- bpf_mov R2, 6
- bpf_mov R3, 7
- bpf_mov R4, 8
- bpf_mov R5, 9
- bpf_call bar
- bpf_add R0, R7
- bpf_exit
-
- After JIT to x86_64 may look like::
-
- push %rbp
- mov %rsp,%rbp
- sub $0x228,%rsp
- mov %rbx,-0x228(%rbp)
- mov %r13,-0x220(%rbp)
- mov %rdi,%rbx
- mov $0x2,%esi
- mov $0x3,%edx
- mov $0x4,%ecx
- mov $0x5,%r8d
- callq foo
- mov %rax,%r13
- mov %rbx,%rdi
- mov $0x6,%esi
- mov $0x7,%edx
- mov $0x8,%ecx
- mov $0x9,%r8d
- callq bar
- add %r13,%rax
- mov -0x228(%rbp),%rbx
- mov -0x220(%rbp),%r13
- leaveq
- retq
-
- Which is in this example equivalent in C to::
-
- u64 bpf_filter(u64 ctx)
- {
- return foo(ctx, 2, 3, 4, 5) + bar(ctx, 6, 7, 8, 9);
- }
-
- In-kernel functions foo() and bar() with prototype: u64 (*)(u64 arg1, u64
- arg2, u64 arg3, u64 arg4, u64 arg5); will receive arguments in proper
- registers and place their return value into ``%rax`` which is R0 in eBPF.
- Prologue and epilogue are emitted by JIT and are implicit in the
- interpreter. R0-R5 are scratch registers, so eBPF program needs to preserve
- them across the calls as defined by calling convention.
-
- For example the following program is invalid::
-
- bpf_mov R1, 1
- bpf_call foo
- bpf_mov R0, R1
- bpf_exit
-
- After the call the registers R1-R5 contain junk values and cannot be read.
- An in-kernel verifier.rst is used to validate eBPF programs.
-
-Also in the new design, eBPF is limited to 4096 insns, which means that any
-program will terminate quickly and will only call a fixed number of kernel
-functions. Original BPF and eBPF are two operand instructions,
-which helps to do one-to-one mapping between eBPF insn and x86 insn during JIT.
-
-The input context pointer for invoking the interpreter function is generic,
-its content is defined by a specific use case. For seccomp register R1 points
-to seccomp_data, for converted BPF filters R1 points to a skb.
-
-A program, that is translated internally consists of the following elements::
-
- op:16, jt:8, jf:8, k:32 ==> op:8, dst_reg:4, src_reg:4, off:16, imm:32
-
-So far 87 eBPF instructions were implemented. 8-bit 'op' opcode field
-has room for new instructions. Some of them may use 16/24/32 byte encoding. New
-instructions must be multiple of 8 bytes to preserve backward compatibility.
-
-eBPF is a general purpose RISC instruction set. Not every register and
-every instruction are used during translation from original BPF to eBPF.
-For example, socket filters are not using ``exclusive add`` instruction, but
-tracing filters may do to maintain counters of events, for example. Register R9
-is not used by socket filters either, but more complex filters may be running
-out of registers and would have to resort to spill/fill to stack.
-
-eBPF can be used as a generic assembler for last step performance
-optimizations, socket filters and seccomp are using it as assembler. Tracing
-filters may use it as assembler to generate code from kernel. In kernel usage
-may not be bounded by security considerations, since generated eBPF code
-may be optimizing internal code path and not being exposed to the user space.
-Safety of eBPF can come from the verifier.rst. In such use cases as
-described, it may be used as safe instruction set.
-
-Just like the original BPF, eBPF runs within a controlled environment,
-is deterministic and the kernel can easily prove that. The safety of the program
-can be determined in two steps: first step does depth-first-search to disallow
-loops and other CFG validation; second step starts from the first insn and
-descends all possible paths. It simulates execution of every insn and observes
-the state change of registers and stack.
+Registers and calling convention
+================================
+
+eBPF has 10 general purpose registers and a read-only frame pointer register,
+all of which are 64-bits wide.
+
+The eBPF calling convention is defined as:
+
+ * R0: return value from function calls, and exit value for eBPF programs
+ * R1 - R5: arguments for function calls
+ * R6 - R9: callee saved registers that function calls will preserve
+ * R10: read-only frame pointer to access stack
+
+R0 - R5 are scratch registers and eBPF programs needs to spill/fill them if
+necessary across calls.
eBPF opcode encoding
====================
new file mode 100644
@@ -0,0 +1,238 @@
+
+====================
+Introduction to eBPF
+====================
+
+eBPF is designed to be JITed with one to one mapping, which can also open up
+the possibility for GCC/LLVM compilers to generate optimized eBPF code through
+an eBPF backend that performs almost as fast as natively compiled code.
+
+Some core changes of the eBPF format from classic BPF:
+
+- Number of registers increase from 2 to 10:
+
+ The old format had two registers A and X, and a hidden frame pointer. The
+ new layout extends this to be 10 internal registers and a read-only frame
+ pointer. Since 64-bit CPUs are passing arguments to functions via registers
+ the number of args from eBPF program to in-kernel function is restricted
+ to 5 and one register is used to accept return value from an in-kernel
+ function. Natively, x86_64 passes first 6 arguments in registers, aarch64/
+ sparcv9/mips64 have 7 - 8 registers for arguments; x86_64 has 6 callee saved
+ registers, and aarch64/sparcv9/mips64 have 11 or more callee saved registers.
+
+ Thus, all eBPF registers map one to one to HW registers on x86_64, aarch64,
+ etc, and eBPF calling convention maps directly to ABIs used by the kernel on
+ 64-bit architectures.
+
+ On 32-bit architectures JIT may map programs that use only 32-bit arithmetic
+ and may let more complex programs to be interpreted.
+
+ R0 - R5 are scratch registers and eBPF program needs spill/fill them if
+ necessary across calls. Note that there is only one eBPF program (== one
+ eBPF main routine) and it cannot call other eBPF functions, it can only
+ call predefined in-kernel functions, though.
+
+- Register width increases from 32-bit to 64-bit:
+
+ Still, the semantics of the original 32-bit ALU operations are preserved
+ via 32-bit subregisters. All eBPF registers are 64-bit with 32-bit lower
+ subregisters that zero-extend into 64-bit if they are being written to.
+ That behavior maps directly to x86_64 and arm64 subregister definition, but
+ makes other JITs more difficult.
+
+ 32-bit architectures run 64-bit eBPF programs via interpreter.
+ Their JITs may convert BPF programs that only use 32-bit subregisters into
+ native instruction set and let the rest being interpreted.
+
+ Operation is 64-bit, because on 64-bit architectures, pointers are also
+ 64-bit wide, and we want to pass 64-bit values in/out of kernel functions,
+ so 32-bit eBPF registers would otherwise require to define register-pair
+ ABI, thus, there won't be able to use a direct eBPF register to HW register
+ mapping and JIT would need to do combine/split/move operations for every
+ register in and out of the function, which is complex, bug prone and slow.
+ Another reason is the use of atomic 64-bit counters.
+
+- Conditional jt/jf targets replaced with jt/fall-through:
+
+ While the original design has constructs such as ``if (cond) jump_true;
+ else jump_false;``, they are being replaced into alternative constructs like
+ ``if (cond) jump_true; /* else fall-through */``.
+
+- Introduces bpf_call insn and register passing convention for zero overhead
+ calls from/to other kernel functions:
+
+ Before an in-kernel function call, the eBPF program needs to
+ place function arguments into R1 to R5 registers to satisfy calling
+ convention, then the interpreter will take them from registers and pass
+ to in-kernel function. If R1 - R5 registers are mapped to CPU registers
+ that are used for argument passing on given architecture, the JIT compiler
+ doesn't need to emit extra moves. Function arguments will be in the correct
+ registers and BPF_CALL instruction will be JITed as single 'call' HW
+ instruction. This calling convention was picked to cover common call
+ situations without performance penalty.
+
+ After an in-kernel function call, R1 - R5 are reset to unreadable and R0 has
+ a return value of the function. Since R6 - R9 are callee saved, their state
+ is preserved across the call.
+
+ For example, consider three C functions::
+
+ u64 f1() { return (*_f2)(1); }
+ u64 f2(u64 a) { return f3(a + 1, a); }
+ u64 f3(u64 a, u64 b) { return a - b; }
+
+ GCC can compile f1, f3 into x86_64::
+
+ f1:
+ movl $1, %edi
+ movq _f2(%rip), %rax
+ jmp *%rax
+ f3:
+ movq %rdi, %rax
+ subq %rsi, %rax
+ ret
+
+ Function f2 in eBPF may look like::
+
+ f2:
+ bpf_mov R2, R1
+ bpf_add R1, 1
+ bpf_call f3
+ bpf_exit
+
+ If f2 is JITed and the pointer stored to ``_f2``. The calls f1 -> f2 -> f3 and
+ returns will be seamless. Without JIT, __bpf_prog_run() interpreter needs to
+ be used to call into f2.
+
+ For practical reasons all eBPF programs have only one argument 'ctx' which is
+ already placed into R1 (e.g. on __bpf_prog_run() startup) and the programs
+ can call kernel functions with up to 5 arguments. Calls with 6 or more arguments
+ are currently not supported, but these restrictions can be lifted if necessary
+ in the future.
+
+ On 64-bit architectures all register map to HW registers one to one. For
+ example, x86_64 JIT compiler can map them as ...
+
+ ::
+
+ R0 - rax
+ R1 - rdi
+ R2 - rsi
+ R3 - rdx
+ R4 - rcx
+ R5 - r8
+ R6 - rbx
+ R7 - r13
+ R8 - r14
+ R9 - r15
+ R10 - rbp
+
+ ... since x86_64 ABI mandates rdi, rsi, rdx, rcx, r8, r9 for argument passing
+ and rbx, r12 - r15 are callee saved.
+
+ Then the following eBPF pseudo-program::
+
+ bpf_mov R6, R1 /* save ctx */
+ bpf_mov R2, 2
+ bpf_mov R3, 3
+ bpf_mov R4, 4
+ bpf_mov R5, 5
+ bpf_call foo
+ bpf_mov R7, R0 /* save foo() return value */
+ bpf_mov R1, R6 /* restore ctx for next call */
+ bpf_mov R2, 6
+ bpf_mov R3, 7
+ bpf_mov R4, 8
+ bpf_mov R5, 9
+ bpf_call bar
+ bpf_add R0, R7
+ bpf_exit
+
+ After JIT to x86_64 may look like::
+
+ push %rbp
+ mov %rsp,%rbp
+ sub $0x228,%rsp
+ mov %rbx,-0x228(%rbp)
+ mov %r13,-0x220(%rbp)
+ mov %rdi,%rbx
+ mov $0x2,%esi
+ mov $0x3,%edx
+ mov $0x4,%ecx
+ mov $0x5,%r8d
+ callq foo
+ mov %rax,%r13
+ mov %rbx,%rdi
+ mov $0x6,%esi
+ mov $0x7,%edx
+ mov $0x8,%ecx
+ mov $0x9,%r8d
+ callq bar
+ add %r13,%rax
+ mov -0x228(%rbp),%rbx
+ mov -0x220(%rbp),%r13
+ leaveq
+ retq
+
+ Which is in this example equivalent in C to::
+
+ u64 bpf_filter(u64 ctx)
+ {
+ return foo(ctx, 2, 3, 4, 5) + bar(ctx, 6, 7, 8, 9);
+ }
+
+ In-kernel functions foo() and bar() with prototype: u64 (*)(u64 arg1, u64
+ arg2, u64 arg3, u64 arg4, u64 arg5); will receive arguments in proper
+ registers and place their return value into ``%rax`` which is R0 in eBPF.
+ Prologue and epilogue are emitted by JIT and are implicit in the
+ interpreter. R0-R5 are scratch registers, so eBPF program needs to preserve
+ them across the calls as defined by calling convention.
+
+ For example the following program is invalid::
+
+ bpf_mov R1, 1
+ bpf_call foo
+ bpf_mov R0, R1
+ bpf_exit
+
+ After the call the registers R1-R5 contain junk values and cannot be read.
+ An in-kernel verifier.rst is used to validate eBPF programs.
+
+Also in the new design, eBPF is limited to 4096 insns, which means that any
+program will terminate quickly and will only call a fixed number of kernel
+functions. Original BPF and eBPF are two operand instructions,
+which helps to do one-to-one mapping between eBPF insn and x86 insn during JIT.
+
+The input context pointer for invoking the interpreter function is generic,
+its content is defined by a specific use case. For seccomp register R1 points
+to seccomp_data, for converted BPF filters R1 points to a skb.
+
+A program, that is translated internally consists of the following elements::
+
+ op:16, jt:8, jf:8, k:32 ==> op:8, dst_reg:4, src_reg:4, off:16, imm:32
+
+So far 87 eBPF instructions were implemented. 8-bit 'op' opcode field
+has room for new instructions. Some of them may use 16/24/32 byte encoding. New
+instructions must be multiple of 8 bytes to preserve backward compatibility.
+
+eBPF is a general purpose RISC instruction set. Not every register and
+every instruction are used during translation from original BPF to eBPF.
+For example, socket filters are not using ``exclusive add`` instruction, but
+tracing filters may do to maintain counters of events, for example. Register R9
+is not used by socket filters either, but more complex filters may be running
+out of registers and would have to resort to spill/fill to stack.
+
+eBPF can be used as a generic assembler for last step performance
+optimizations, socket filters and seccomp are using it as assembler. Tracing
+filters may use it as assembler to generate code from kernel. In kernel usage
+may not be bounded by security considerations, since generated eBPF code
+may be optimizing internal code path and not being exposed to the user space.
+Safety of eBPF can come from the verifier.rst. In such use cases as
+described, it may be used as safe instruction set.
+
+Just like the original BPF, eBPF runs within a controlled environment,
+is deterministic and the kernel can easily prove that. The safety of the program
+can be determined in two steps: first step does depth-first-search to disallow
+loops and other CFG validation; second step starts from the first insn and
+descends all possible paths. It simulates execution of every insn and observes
+the state change of registers and stack.
Split the introductory that explain eBPF vs classic BPF and how it maps to hardware from the instruction set specification into a standalone document. Because this introduction was the only place explaining the register set and calling conventins keep those in the main instruction set document after a small refactoring. Signed-off-by: Christoph Hellwig <hch@lst.de> --- Documentation/bpf/index.rst | 1 + Documentation/bpf/instruction-set.rst | 255 ++------------------------ Documentation/bpf/intro.rst | 238 ++++++++++++++++++++++++ 3 files changed, 254 insertions(+), 240 deletions(-) create mode 100644 Documentation/bpf/intro.rst