linux/arch/mips/net/bpf_jit_comp.c

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mips, bpf: Add eBPF JIT for 32-bit MIPS This is an implementation of an eBPF JIT for 32-bit MIPS I-V and MIPS32. The implementation supports all 32-bit and 64-bit ALU and JMP operations, including the recently-added atomics. 64-bit div/mod and 64-bit atomics are implemented using function calls to math64 and atomic64 functions, respectively. All 32-bit operations are implemented natively by the JIT, except if the CPU lacks ll/sc instructions. Register mapping ================ All 64-bit eBPF registers are mapped to native 32-bit MIPS register pairs, and does not use any stack scratch space for register swapping. This means that all eBPF register data is kept in CPU registers all the time, and this simplifies the register management a lot. It also reduces the JIT's pressure on temporary registers since we do not have to move data around. Native register pairs are ordered according to CPU endiannes, following the O32 calling convention for passing 64-bit arguments and return values. The eBPF return value, arguments and callee-saved registers are mapped to their native MIPS equivalents. Since the 32 highest bits in the eBPF FP (frame pointer) register are always zero, only one general-purpose register is actually needed for the mapping. The MIPS fp register is used for this purpose. The high bits are mapped to MIPS register r0. This saves us one CPU register, which is much needed for temporaries, while still allowing us to treat the R10 (FP) register just like any other eBPF register in the JIT. The MIPS gp (global pointer) and at (assembler temporary) registers are used as internal temporary registers for constant blinding. CPU registers t6-t9 are used internally by the JIT when constructing more complex 64-bit operations. This is precisely what is needed - two registers to store an operand value, and two more as scratch registers when performing the operation. The register mapping is shown below. R0 - $v1, $v0 return value R1 - $a1, $a0 argument 1, passed in registers R2 - $a3, $a2 argument 2, passed in registers R3 - $t1, $t0 argument 3, passed on stack R4 - $t3, $t2 argument 4, passed on stack R5 - $t4, $t3 argument 5, passed on stack R6 - $s1, $s0 callee-saved R7 - $s3, $s2 callee-saved R8 - $s5, $s4 callee-saved R9 - $s7, $s6 callee-saved FP - $r0, $fp 32-bit frame pointer AX - $gp, $at constant-blinding $t6 - $t9 unallocated, JIT temporaries Jump offsets ============ The JIT tries to map all conditional JMP operations to MIPS conditional PC-relative branches. The MIPS branch offset field is 18 bits, in bytes, which is equivalent to the eBPF 16-bit instruction offset. However, since the JIT may emit more than one CPU instruction per eBPF instruction, the field width may overflow. If that happens, the JIT converts the long conditional jump to a short PC-relative branch with the condition inverted, jumping over a long unconditional absolute jmp (j). This conversion will change the instruction offset mapping used for jumps, and may in turn result in more branch offset overflows. The JIT therefore dry-runs the translation until no more branches are converted and the offsets do not change anymore. There is an upper bound on this of course, and if the JIT hits that limit, the last two iterations are run with all branches being converted. Tail call count =============== The current tail call count is stored in the 16-byte area of the caller's stack frame that is reserved for the callee in the o32 ABI. The value is initialized in the prologue, and propagated to the tail-callee by skipping the initialization instructions when emitting the tail call. Signed-off-by: Johan Almbladh <johan.almbladh@anyfinetworks.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net> Signed-off-by: Andrii Nakryiko <andrii@kernel.org> Link: https://lore.kernel.org/bpf/20211005165408.2305108-4-johan.almbladh@anyfinetworks.com
2021-10-05 16:54:04 +00:00
// SPDX-License-Identifier: GPL-2.0-only
/*
* Just-In-Time compiler for eBPF bytecode on MIPS.
* Implementation of JIT functions common to 32-bit and 64-bit CPUs.
*
* Copyright (c) 2021 Anyfi Networks AB.
* Author: Johan Almbladh <johan.almbladh@gmail.com>
*
* Based on code and ideas from
* Copyright (c) 2017 Cavium, Inc.
* Copyright (c) 2017 Shubham Bansal <illusionist.neo@gmail.com>
* Copyright (c) 2011 Mircea Gherzan <mgherzan@gmail.com>
*/
/*
* Code overview
* =============
*
* - bpf_jit_comp.h
* Common definitions and utilities.
*
* - bpf_jit_comp.c
* Implementation of JIT top-level logic and exported JIT API functions.
* Implementation of internal operations shared by 32-bit and 64-bit code.
* JMP and ALU JIT control code, register control code, shared ALU and
* JMP/JMP32 JIT operations.
*
* - bpf_jit_comp32.c
* Implementation of functions to JIT prologue, epilogue and a single eBPF
* instruction for 32-bit MIPS CPUs. The functions use shared operations
* where possible, and implement the rest for 32-bit MIPS such as ALU64
* operations.
*
* - bpf_jit_comp64.c
* Ditto, for 64-bit MIPS CPUs.
*
* Zero and sign extension
* ========================
* 32-bit MIPS instructions on 64-bit MIPS registers use sign extension,
* but the eBPF instruction set mandates zero extension. We let the verifier
* insert explicit zero-extensions after 32-bit ALU operations, both for
* 32-bit and 64-bit MIPS JITs. Conditional JMP32 operations on 64-bit MIPs
* are JITed with sign extensions inserted when so expected.
*
* ALU operations
* ==============
* ALU operations on 32/64-bit MIPS and ALU64 operations on 64-bit MIPS are
* JITed in the following steps. ALU64 operations on 32-bit MIPS are more
* complicated and therefore only processed by special implementations in
* step (3).
*
* 1) valid_alu_i:
* Determine if an immediate operation can be emitted as such, or if
* we must fall back to the register version.
*
* 2) rewrite_alu_i:
* Convert BPF operation and immediate value to a canonical form for
* JITing. In some degenerate cases this form may be a no-op.
*
* 3) emit_alu_{i,i64,r,64}:
* Emit instructions for an ALU or ALU64 immediate or register operation.
*
* JMP operations
* ==============
* JMP and JMP32 operations require an JIT instruction offset table for
* translating the jump offset. This table is computed by dry-running the
* JIT without actually emitting anything. However, the computed PC-relative
* offset may overflow the 18-bit offset field width of the native MIPS
* branch instruction. In such cases, the long jump is converted into the
* following sequence.
*
* <branch> !<cond> +2 Inverted PC-relative branch
* nop Delay slot
* j <offset> Unconditional absolute long jump
* nop Delay slot
*
* Since this converted sequence alters the offset table, all offsets must
* be re-calculated. This may in turn trigger new branch conversions, so
* the process is repeated until no further changes are made. Normally it
* completes in 1-2 iterations. If JIT_MAX_ITERATIONS should reached, we
* fall back to converting every remaining jump operation. The branch
* conversion is independent of how the JMP or JMP32 condition is JITed.
*
* JMP32 and JMP operations are JITed as follows.
*
* 1) setup_jmp_{i,r}:
* Convert jump conditional and offset into a form that can be JITed.
* This form may be a no-op, a canonical form, or an inverted PC-relative
* jump if branch conversion is necessary.
*
* 2) valid_jmp_i:
* Determine if an immediate operations can be emitted as such, or if
* we must fall back to the register version. Applies to JMP32 for 32-bit
* MIPS, and both JMP and JMP32 for 64-bit MIPS.
*
* 3) emit_jmp_{i,i64,r,r64}:
* Emit instructions for an JMP or JMP32 immediate or register operation.
*
* 4) finish_jmp_{i,r}:
* Emit any instructions needed to finish the jump. This includes a nop
* for the delay slot if a branch was emitted, and a long absolute jump
* if the branch was converted.
*/
#include <linux/limits.h>
#include <linux/bitops.h>
#include <linux/errno.h>
#include <linux/filter.h>
#include <linux/bpf.h>
#include <linux/slab.h>
#include <asm/bitops.h>
#include <asm/cacheflush.h>
#include <asm/cpu-features.h>
#include <asm/isa-rev.h>
#include <asm/uasm.h>
#include "bpf_jit_comp.h"
/* Convenience macros for descriptor access */
#define CONVERTED(desc) ((desc) & JIT_DESC_CONVERT)
#define INDEX(desc) ((desc) & ~JIT_DESC_CONVERT)
/*
* Push registers on the stack, starting at a given depth from the stack
* pointer and increasing. The next depth to be written is returned.
*/
int push_regs(struct jit_context *ctx, u32 mask, u32 excl, int depth)
{
int reg;
for (reg = 0; reg < BITS_PER_BYTE * sizeof(mask); reg++)
if (mask & BIT(reg)) {
if ((excl & BIT(reg)) == 0) {
if (sizeof(long) == 4)
emit(ctx, sw, reg, depth, MIPS_R_SP);
else /* sizeof(long) == 8 */
emit(ctx, sd, reg, depth, MIPS_R_SP);
}
depth += sizeof(long);
}
ctx->stack_used = max((int)ctx->stack_used, depth);
return depth;
}
/*
* Pop registers from the stack, starting at a given depth from the stack
* pointer and increasing. The next depth to be read is returned.
*/
int pop_regs(struct jit_context *ctx, u32 mask, u32 excl, int depth)
{
int reg;
for (reg = 0; reg < BITS_PER_BYTE * sizeof(mask); reg++)
if (mask & BIT(reg)) {
if ((excl & BIT(reg)) == 0) {
if (sizeof(long) == 4)
emit(ctx, lw, reg, depth, MIPS_R_SP);
else /* sizeof(long) == 8 */
emit(ctx, ld, reg, depth, MIPS_R_SP);
}
depth += sizeof(long);
}
return depth;
}
/* Compute the 28-bit jump target address from a BPF program location */
int get_target(struct jit_context *ctx, u32 loc)
{
u32 index = INDEX(ctx->descriptors[loc]);
unsigned long pc = (unsigned long)&ctx->target[ctx->jit_index];
unsigned long addr = (unsigned long)&ctx->target[index];
if (!ctx->target)
return 0;
if ((addr ^ pc) & ~MIPS_JMP_MASK)
return -1;
return addr & MIPS_JMP_MASK;
}
/* Compute the PC-relative offset to relative BPF program offset */
int get_offset(const struct jit_context *ctx, int off)
{
return (INDEX(ctx->descriptors[ctx->bpf_index + off]) -
ctx->jit_index - 1) * sizeof(u32);
}
/* dst = imm (register width) */
void emit_mov_i(struct jit_context *ctx, u8 dst, s32 imm)
{
if (imm >= -0x8000 && imm <= 0x7fff) {
emit(ctx, addiu, dst, MIPS_R_ZERO, imm);
} else {
emit(ctx, lui, dst, (s16)((u32)imm >> 16));
emit(ctx, ori, dst, dst, (u16)(imm & 0xffff));
}
clobber_reg(ctx, dst);
}
/* dst = src (register width) */
void emit_mov_r(struct jit_context *ctx, u8 dst, u8 src)
{
emit(ctx, ori, dst, src, 0);
clobber_reg(ctx, dst);
}
/* Validate ALU immediate range */
bool valid_alu_i(u8 op, s32 imm)
{
switch (BPF_OP(op)) {
case BPF_NEG:
case BPF_LSH:
case BPF_RSH:
case BPF_ARSH:
/* All legal eBPF values are valid */
return true;
case BPF_ADD:
/* imm must be 16 bits */
return imm >= -0x8000 && imm <= 0x7fff;
case BPF_SUB:
/* -imm must be 16 bits */
return imm >= -0x7fff && imm <= 0x8000;
case BPF_AND:
case BPF_OR:
case BPF_XOR:
/* imm must be 16 bits unsigned */
return imm >= 0 && imm <= 0xffff;
case BPF_MUL:
/* imm must be zero or a positive power of two */
return imm == 0 || (imm > 0 && is_power_of_2(imm));
case BPF_DIV:
case BPF_MOD:
/* imm must be an 17-bit power of two */
return (u32)imm <= 0x10000 && is_power_of_2((u32)imm);
}
return false;
}
/* Rewrite ALU immediate operation */
bool rewrite_alu_i(u8 op, s32 imm, u8 *alu, s32 *val)
{
bool act = true;
switch (BPF_OP(op)) {
case BPF_LSH:
case BPF_RSH:
case BPF_ARSH:
case BPF_ADD:
case BPF_SUB:
case BPF_OR:
case BPF_XOR:
/* imm == 0 is a no-op */
act = imm != 0;
break;
case BPF_MUL:
if (imm == 1) {
/* dst * 1 is a no-op */
act = false;
} else if (imm == 0) {
/* dst * 0 is dst & 0 */
op = BPF_AND;
} else {
/* dst * (1 << n) is dst << n */
op = BPF_LSH;
imm = ilog2(abs(imm));
}
break;
case BPF_DIV:
if (imm == 1) {
/* dst / 1 is a no-op */
act = false;
} else {
/* dst / (1 << n) is dst >> n */
op = BPF_RSH;
imm = ilog2(imm);
}
break;
case BPF_MOD:
/* dst % (1 << n) is dst & ((1 << n) - 1) */
op = BPF_AND;
imm--;
break;
}
*alu = op;
*val = imm;
return act;
}
/* ALU immediate operation (32-bit) */
void emit_alu_i(struct jit_context *ctx, u8 dst, s32 imm, u8 op)
{
switch (BPF_OP(op)) {
/* dst = -dst */
case BPF_NEG:
emit(ctx, subu, dst, MIPS_R_ZERO, dst);
break;
/* dst = dst & imm */
case BPF_AND:
emit(ctx, andi, dst, dst, (u16)imm);
break;
/* dst = dst | imm */
case BPF_OR:
emit(ctx, ori, dst, dst, (u16)imm);
break;
/* dst = dst ^ imm */
case BPF_XOR:
emit(ctx, xori, dst, dst, (u16)imm);
break;
/* dst = dst << imm */
case BPF_LSH:
emit(ctx, sll, dst, dst, imm);
break;
/* dst = dst >> imm */
case BPF_RSH:
emit(ctx, srl, dst, dst, imm);
break;
/* dst = dst >> imm (arithmetic) */
case BPF_ARSH:
emit(ctx, sra, dst, dst, imm);
break;
/* dst = dst + imm */
case BPF_ADD:
emit(ctx, addiu, dst, dst, imm);
break;
/* dst = dst - imm */
case BPF_SUB:
emit(ctx, addiu, dst, dst, -imm);
break;
}
clobber_reg(ctx, dst);
}
/* ALU register operation (32-bit) */
void emit_alu_r(struct jit_context *ctx, u8 dst, u8 src, u8 op)
{
switch (BPF_OP(op)) {
/* dst = dst & src */
case BPF_AND:
emit(ctx, and, dst, dst, src);
break;
/* dst = dst | src */
case BPF_OR:
emit(ctx, or, dst, dst, src);
break;
/* dst = dst ^ src */
case BPF_XOR:
emit(ctx, xor, dst, dst, src);
break;
/* dst = dst << src */
case BPF_LSH:
emit(ctx, sllv, dst, dst, src);
break;
/* dst = dst >> src */
case BPF_RSH:
emit(ctx, srlv, dst, dst, src);
break;
/* dst = dst >> src (arithmetic) */
case BPF_ARSH:
emit(ctx, srav, dst, dst, src);
break;
/* dst = dst + src */
case BPF_ADD:
emit(ctx, addu, dst, dst, src);
break;
/* dst = dst - src */
case BPF_SUB:
emit(ctx, subu, dst, dst, src);
break;
/* dst = dst * src */
case BPF_MUL:
if (cpu_has_mips32r1 || cpu_has_mips32r6) {
emit(ctx, mul, dst, dst, src);
} else {
emit(ctx, multu, dst, src);
emit(ctx, mflo, dst);
}
break;
/* dst = dst / src */
case BPF_DIV:
if (cpu_has_mips32r6) {
emit(ctx, divu_r6, dst, dst, src);
} else {
emit(ctx, divu, dst, src);
emit(ctx, mflo, dst);
}
break;
/* dst = dst % src */
case BPF_MOD:
if (cpu_has_mips32r6) {
emit(ctx, modu, dst, dst, src);
} else {
emit(ctx, divu, dst, src);
emit(ctx, mfhi, dst);
}
break;
}
clobber_reg(ctx, dst);
}
/* Atomic read-modify-write (32-bit) */
void emit_atomic_r(struct jit_context *ctx, u8 dst, u8 src, s16 off, u8 code)
{
LLSC_sync(ctx);
mips, bpf: Add eBPF JIT for 32-bit MIPS This is an implementation of an eBPF JIT for 32-bit MIPS I-V and MIPS32. The implementation supports all 32-bit and 64-bit ALU and JMP operations, including the recently-added atomics. 64-bit div/mod and 64-bit atomics are implemented using function calls to math64 and atomic64 functions, respectively. All 32-bit operations are implemented natively by the JIT, except if the CPU lacks ll/sc instructions. Register mapping ================ All 64-bit eBPF registers are mapped to native 32-bit MIPS register pairs, and does not use any stack scratch space for register swapping. This means that all eBPF register data is kept in CPU registers all the time, and this simplifies the register management a lot. It also reduces the JIT's pressure on temporary registers since we do not have to move data around. Native register pairs are ordered according to CPU endiannes, following the O32 calling convention for passing 64-bit arguments and return values. The eBPF return value, arguments and callee-saved registers are mapped to their native MIPS equivalents. Since the 32 highest bits in the eBPF FP (frame pointer) register are always zero, only one general-purpose register is actually needed for the mapping. The MIPS fp register is used for this purpose. The high bits are mapped to MIPS register r0. This saves us one CPU register, which is much needed for temporaries, while still allowing us to treat the R10 (FP) register just like any other eBPF register in the JIT. The MIPS gp (global pointer) and at (assembler temporary) registers are used as internal temporary registers for constant blinding. CPU registers t6-t9 are used internally by the JIT when constructing more complex 64-bit operations. This is precisely what is needed - two registers to store an operand value, and two more as scratch registers when performing the operation. The register mapping is shown below. R0 - $v1, $v0 return value R1 - $a1, $a0 argument 1, passed in registers R2 - $a3, $a2 argument 2, passed in registers R3 - $t1, $t0 argument 3, passed on stack R4 - $t3, $t2 argument 4, passed on stack R5 - $t4, $t3 argument 5, passed on stack R6 - $s1, $s0 callee-saved R7 - $s3, $s2 callee-saved R8 - $s5, $s4 callee-saved R9 - $s7, $s6 callee-saved FP - $r0, $fp 32-bit frame pointer AX - $gp, $at constant-blinding $t6 - $t9 unallocated, JIT temporaries Jump offsets ============ The JIT tries to map all conditional JMP operations to MIPS conditional PC-relative branches. The MIPS branch offset field is 18 bits, in bytes, which is equivalent to the eBPF 16-bit instruction offset. However, since the JIT may emit more than one CPU instruction per eBPF instruction, the field width may overflow. If that happens, the JIT converts the long conditional jump to a short PC-relative branch with the condition inverted, jumping over a long unconditional absolute jmp (j). This conversion will change the instruction offset mapping used for jumps, and may in turn result in more branch offset overflows. The JIT therefore dry-runs the translation until no more branches are converted and the offsets do not change anymore. There is an upper bound on this of course, and if the JIT hits that limit, the last two iterations are run with all branches being converted. Tail call count =============== The current tail call count is stored in the 16-byte area of the caller's stack frame that is reserved for the callee in the o32 ABI. The value is initialized in the prologue, and propagated to the tail-callee by skipping the initialization instructions when emitting the tail call. Signed-off-by: Johan Almbladh <johan.almbladh@anyfinetworks.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net> Signed-off-by: Andrii Nakryiko <andrii@kernel.org> Link: https://lore.kernel.org/bpf/20211005165408.2305108-4-johan.almbladh@anyfinetworks.com
2021-10-05 16:54:04 +00:00
emit(ctx, ll, MIPS_R_T9, off, dst);
switch (code) {
case BPF_ADD:
case BPF_ADD | BPF_FETCH:
emit(ctx, addu, MIPS_R_T8, MIPS_R_T9, src);
break;
case BPF_AND:
case BPF_AND | BPF_FETCH:
emit(ctx, and, MIPS_R_T8, MIPS_R_T9, src);
break;
case BPF_OR:
case BPF_OR | BPF_FETCH:
emit(ctx, or, MIPS_R_T8, MIPS_R_T9, src);
break;
case BPF_XOR:
case BPF_XOR | BPF_FETCH:
emit(ctx, xor, MIPS_R_T8, MIPS_R_T9, src);
break;
case BPF_XCHG:
emit(ctx, move, MIPS_R_T8, src);
break;
}
emit(ctx, sc, MIPS_R_T8, off, dst);
emit(ctx, LLSC_beqz, MIPS_R_T8, -16 - LLSC_offset);
mips, bpf: Add eBPF JIT for 32-bit MIPS This is an implementation of an eBPF JIT for 32-bit MIPS I-V and MIPS32. The implementation supports all 32-bit and 64-bit ALU and JMP operations, including the recently-added atomics. 64-bit div/mod and 64-bit atomics are implemented using function calls to math64 and atomic64 functions, respectively. All 32-bit operations are implemented natively by the JIT, except if the CPU lacks ll/sc instructions. Register mapping ================ All 64-bit eBPF registers are mapped to native 32-bit MIPS register pairs, and does not use any stack scratch space for register swapping. This means that all eBPF register data is kept in CPU registers all the time, and this simplifies the register management a lot. It also reduces the JIT's pressure on temporary registers since we do not have to move data around. Native register pairs are ordered according to CPU endiannes, following the O32 calling convention for passing 64-bit arguments and return values. The eBPF return value, arguments and callee-saved registers are mapped to their native MIPS equivalents. Since the 32 highest bits in the eBPF FP (frame pointer) register are always zero, only one general-purpose register is actually needed for the mapping. The MIPS fp register is used for this purpose. The high bits are mapped to MIPS register r0. This saves us one CPU register, which is much needed for temporaries, while still allowing us to treat the R10 (FP) register just like any other eBPF register in the JIT. The MIPS gp (global pointer) and at (assembler temporary) registers are used as internal temporary registers for constant blinding. CPU registers t6-t9 are used internally by the JIT when constructing more complex 64-bit operations. This is precisely what is needed - two registers to store an operand value, and two more as scratch registers when performing the operation. The register mapping is shown below. R0 - $v1, $v0 return value R1 - $a1, $a0 argument 1, passed in registers R2 - $a3, $a2 argument 2, passed in registers R3 - $t1, $t0 argument 3, passed on stack R4 - $t3, $t2 argument 4, passed on stack R5 - $t4, $t3 argument 5, passed on stack R6 - $s1, $s0 callee-saved R7 - $s3, $s2 callee-saved R8 - $s5, $s4 callee-saved R9 - $s7, $s6 callee-saved FP - $r0, $fp 32-bit frame pointer AX - $gp, $at constant-blinding $t6 - $t9 unallocated, JIT temporaries Jump offsets ============ The JIT tries to map all conditional JMP operations to MIPS conditional PC-relative branches. The MIPS branch offset field is 18 bits, in bytes, which is equivalent to the eBPF 16-bit instruction offset. However, since the JIT may emit more than one CPU instruction per eBPF instruction, the field width may overflow. If that happens, the JIT converts the long conditional jump to a short PC-relative branch with the condition inverted, jumping over a long unconditional absolute jmp (j). This conversion will change the instruction offset mapping used for jumps, and may in turn result in more branch offset overflows. The JIT therefore dry-runs the translation until no more branches are converted and the offsets do not change anymore. There is an upper bound on this of course, and if the JIT hits that limit, the last two iterations are run with all branches being converted. Tail call count =============== The current tail call count is stored in the 16-byte area of the caller's stack frame that is reserved for the callee in the o32 ABI. The value is initialized in the prologue, and propagated to the tail-callee by skipping the initialization instructions when emitting the tail call. Signed-off-by: Johan Almbladh <johan.almbladh@anyfinetworks.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net> Signed-off-by: Andrii Nakryiko <andrii@kernel.org> Link: https://lore.kernel.org/bpf/20211005165408.2305108-4-johan.almbladh@anyfinetworks.com
2021-10-05 16:54:04 +00:00
emit(ctx, nop); /* Delay slot */
if (code & BPF_FETCH) {
emit(ctx, move, src, MIPS_R_T9);
clobber_reg(ctx, src);
}
}
/* Atomic compare-and-exchange (32-bit) */
void emit_cmpxchg_r(struct jit_context *ctx, u8 dst, u8 src, u8 res, s16 off)
{
LLSC_sync(ctx);
mips, bpf: Add eBPF JIT for 32-bit MIPS This is an implementation of an eBPF JIT for 32-bit MIPS I-V and MIPS32. The implementation supports all 32-bit and 64-bit ALU and JMP operations, including the recently-added atomics. 64-bit div/mod and 64-bit atomics are implemented using function calls to math64 and atomic64 functions, respectively. All 32-bit operations are implemented natively by the JIT, except if the CPU lacks ll/sc instructions. Register mapping ================ All 64-bit eBPF registers are mapped to native 32-bit MIPS register pairs, and does not use any stack scratch space for register swapping. This means that all eBPF register data is kept in CPU registers all the time, and this simplifies the register management a lot. It also reduces the JIT's pressure on temporary registers since we do not have to move data around. Native register pairs are ordered according to CPU endiannes, following the O32 calling convention for passing 64-bit arguments and return values. The eBPF return value, arguments and callee-saved registers are mapped to their native MIPS equivalents. Since the 32 highest bits in the eBPF FP (frame pointer) register are always zero, only one general-purpose register is actually needed for the mapping. The MIPS fp register is used for this purpose. The high bits are mapped to MIPS register r0. This saves us one CPU register, which is much needed for temporaries, while still allowing us to treat the R10 (FP) register just like any other eBPF register in the JIT. The MIPS gp (global pointer) and at (assembler temporary) registers are used as internal temporary registers for constant blinding. CPU registers t6-t9 are used internally by the JIT when constructing more complex 64-bit operations. This is precisely what is needed - two registers to store an operand value, and two more as scratch registers when performing the operation. The register mapping is shown below. R0 - $v1, $v0 return value R1 - $a1, $a0 argument 1, passed in registers R2 - $a3, $a2 argument 2, passed in registers R3 - $t1, $t0 argument 3, passed on stack R4 - $t3, $t2 argument 4, passed on stack R5 - $t4, $t3 argument 5, passed on stack R6 - $s1, $s0 callee-saved R7 - $s3, $s2 callee-saved R8 - $s5, $s4 callee-saved R9 - $s7, $s6 callee-saved FP - $r0, $fp 32-bit frame pointer AX - $gp, $at constant-blinding $t6 - $t9 unallocated, JIT temporaries Jump offsets ============ The JIT tries to map all conditional JMP operations to MIPS conditional PC-relative branches. The MIPS branch offset field is 18 bits, in bytes, which is equivalent to the eBPF 16-bit instruction offset. However, since the JIT may emit more than one CPU instruction per eBPF instruction, the field width may overflow. If that happens, the JIT converts the long conditional jump to a short PC-relative branch with the condition inverted, jumping over a long unconditional absolute jmp (j). This conversion will change the instruction offset mapping used for jumps, and may in turn result in more branch offset overflows. The JIT therefore dry-runs the translation until no more branches are converted and the offsets do not change anymore. There is an upper bound on this of course, and if the JIT hits that limit, the last two iterations are run with all branches being converted. Tail call count =============== The current tail call count is stored in the 16-byte area of the caller's stack frame that is reserved for the callee in the o32 ABI. The value is initialized in the prologue, and propagated to the tail-callee by skipping the initialization instructions when emitting the tail call. Signed-off-by: Johan Almbladh <johan.almbladh@anyfinetworks.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net> Signed-off-by: Andrii Nakryiko <andrii@kernel.org> Link: https://lore.kernel.org/bpf/20211005165408.2305108-4-johan.almbladh@anyfinetworks.com
2021-10-05 16:54:04 +00:00
emit(ctx, ll, MIPS_R_T9, off, dst);
emit(ctx, bne, MIPS_R_T9, res, 12);
emit(ctx, move, MIPS_R_T8, src); /* Delay slot */
emit(ctx, sc, MIPS_R_T8, off, dst);
emit(ctx, LLSC_beqz, MIPS_R_T8, -20 - LLSC_offset);
mips, bpf: Add eBPF JIT for 32-bit MIPS This is an implementation of an eBPF JIT for 32-bit MIPS I-V and MIPS32. The implementation supports all 32-bit and 64-bit ALU and JMP operations, including the recently-added atomics. 64-bit div/mod and 64-bit atomics are implemented using function calls to math64 and atomic64 functions, respectively. All 32-bit operations are implemented natively by the JIT, except if the CPU lacks ll/sc instructions. Register mapping ================ All 64-bit eBPF registers are mapped to native 32-bit MIPS register pairs, and does not use any stack scratch space for register swapping. This means that all eBPF register data is kept in CPU registers all the time, and this simplifies the register management a lot. It also reduces the JIT's pressure on temporary registers since we do not have to move data around. Native register pairs are ordered according to CPU endiannes, following the O32 calling convention for passing 64-bit arguments and return values. The eBPF return value, arguments and callee-saved registers are mapped to their native MIPS equivalents. Since the 32 highest bits in the eBPF FP (frame pointer) register are always zero, only one general-purpose register is actually needed for the mapping. The MIPS fp register is used for this purpose. The high bits are mapped to MIPS register r0. This saves us one CPU register, which is much needed for temporaries, while still allowing us to treat the R10 (FP) register just like any other eBPF register in the JIT. The MIPS gp (global pointer) and at (assembler temporary) registers are used as internal temporary registers for constant blinding. CPU registers t6-t9 are used internally by the JIT when constructing more complex 64-bit operations. This is precisely what is needed - two registers to store an operand value, and two more as scratch registers when performing the operation. The register mapping is shown below. R0 - $v1, $v0 return value R1 - $a1, $a0 argument 1, passed in registers R2 - $a3, $a2 argument 2, passed in registers R3 - $t1, $t0 argument 3, passed on stack R4 - $t3, $t2 argument 4, passed on stack R5 - $t4, $t3 argument 5, passed on stack R6 - $s1, $s0 callee-saved R7 - $s3, $s2 callee-saved R8 - $s5, $s4 callee-saved R9 - $s7, $s6 callee-saved FP - $r0, $fp 32-bit frame pointer AX - $gp, $at constant-blinding $t6 - $t9 unallocated, JIT temporaries Jump offsets ============ The JIT tries to map all conditional JMP operations to MIPS conditional PC-relative branches. The MIPS branch offset field is 18 bits, in bytes, which is equivalent to the eBPF 16-bit instruction offset. However, since the JIT may emit more than one CPU instruction per eBPF instruction, the field width may overflow. If that happens, the JIT converts the long conditional jump to a short PC-relative branch with the condition inverted, jumping over a long unconditional absolute jmp (j). This conversion will change the instruction offset mapping used for jumps, and may in turn result in more branch offset overflows. The JIT therefore dry-runs the translation until no more branches are converted and the offsets do not change anymore. There is an upper bound on this of course, and if the JIT hits that limit, the last two iterations are run with all branches being converted. Tail call count =============== The current tail call count is stored in the 16-byte area of the caller's stack frame that is reserved for the callee in the o32 ABI. The value is initialized in the prologue, and propagated to the tail-callee by skipping the initialization instructions when emitting the tail call. Signed-off-by: Johan Almbladh <johan.almbladh@anyfinetworks.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net> Signed-off-by: Andrii Nakryiko <andrii@kernel.org> Link: https://lore.kernel.org/bpf/20211005165408.2305108-4-johan.almbladh@anyfinetworks.com
2021-10-05 16:54:04 +00:00
emit(ctx, move, res, MIPS_R_T9); /* Delay slot */
clobber_reg(ctx, res);
}
/* Swap bytes and truncate a register word or half word */
void emit_bswap_r(struct jit_context *ctx, u8 dst, u32 width)
{
u8 tmp = MIPS_R_T8;
u8 msk = MIPS_R_T9;
switch (width) {
/* Swap bytes in a word */
case 32:
if (cpu_has_mips32r2 || cpu_has_mips32r6) {
emit(ctx, wsbh, dst, dst);
emit(ctx, rotr, dst, dst, 16);
} else {
emit(ctx, sll, tmp, dst, 16); /* tmp = dst << 16 */
emit(ctx, srl, dst, dst, 16); /* dst = dst >> 16 */
emit(ctx, or, dst, dst, tmp); /* dst = dst | tmp */
emit(ctx, lui, msk, 0xff); /* msk = 0x00ff0000 */
emit(ctx, ori, msk, msk, 0xff); /* msk = msk | 0xff */
emit(ctx, and, tmp, dst, msk); /* tmp = dst & msk */
emit(ctx, sll, tmp, tmp, 8); /* tmp = tmp << 8 */
emit(ctx, srl, dst, dst, 8); /* dst = dst >> 8 */
emit(ctx, and, dst, dst, msk); /* dst = dst & msk */
emit(ctx, or, dst, dst, tmp); /* reg = dst | tmp */
}
break;
/* Swap bytes in a half word */
case 16:
if (cpu_has_mips32r2 || cpu_has_mips32r6) {
emit(ctx, wsbh, dst, dst);
emit(ctx, andi, dst, dst, 0xffff);
} else {
emit(ctx, andi, tmp, dst, 0xff00); /* t = d & 0xff00 */
emit(ctx, srl, tmp, tmp, 8); /* t = t >> 8 */
emit(ctx, andi, dst, dst, 0x00ff); /* d = d & 0x00ff */
emit(ctx, sll, dst, dst, 8); /* d = d << 8 */
emit(ctx, or, dst, dst, tmp); /* d = d | t */
}
break;
}
clobber_reg(ctx, dst);
}
/* Validate jump immediate range */
bool valid_jmp_i(u8 op, s32 imm)
{
switch (op) {
case JIT_JNOP:
/* Immediate value not used */
return true;
case BPF_JEQ:
case BPF_JNE:
/* No immediate operation */
return false;
case BPF_JSET:
case JIT_JNSET:
/* imm must be 16 bits unsigned */
return imm >= 0 && imm <= 0xffff;
case BPF_JGE:
case BPF_JLT:
case BPF_JSGE:
case BPF_JSLT:
/* imm must be 16 bits */
return imm >= -0x8000 && imm <= 0x7fff;
case BPF_JGT:
case BPF_JLE:
case BPF_JSGT:
case BPF_JSLE:
/* imm + 1 must be 16 bits */
return imm >= -0x8001 && imm <= 0x7ffe;
}
return false;
}
/* Invert a conditional jump operation */
static u8 invert_jmp(u8 op)
{
switch (op) {
case BPF_JA: return JIT_JNOP;
case BPF_JEQ: return BPF_JNE;
case BPF_JNE: return BPF_JEQ;
case BPF_JSET: return JIT_JNSET;
case BPF_JGT: return BPF_JLE;
case BPF_JGE: return BPF_JLT;
case BPF_JLT: return BPF_JGE;
case BPF_JLE: return BPF_JGT;
case BPF_JSGT: return BPF_JSLE;
case BPF_JSGE: return BPF_JSLT;
case BPF_JSLT: return BPF_JSGE;
case BPF_JSLE: return BPF_JSGT;
}
return 0;
}
/* Prepare a PC-relative jump operation */
static void setup_jmp(struct jit_context *ctx, u8 bpf_op,
s16 bpf_off, u8 *jit_op, s32 *jit_off)
{
u32 *descp = &ctx->descriptors[ctx->bpf_index];
int op = bpf_op;
int offset = 0;
/* Do not compute offsets on the first pass */
if (INDEX(*descp) == 0)
goto done;
/* Skip jumps never taken */
if (bpf_op == JIT_JNOP)
goto done;
/* Convert jumps always taken */
if (bpf_op == BPF_JA)
*descp |= JIT_DESC_CONVERT;
/*
* Current ctx->jit_index points to the start of the branch preamble.
* Since the preamble differs among different branch conditionals,
* the current index cannot be used to compute the branch offset.
* Instead, we use the offset table value for the next instruction,
* which gives the index immediately after the branch delay slot.
*/
if (!CONVERTED(*descp)) {
int target = ctx->bpf_index + bpf_off + 1;
int origin = ctx->bpf_index + 1;
offset = (INDEX(ctx->descriptors[target]) -
INDEX(ctx->descriptors[origin]) + 1) * sizeof(u32);
}
/*
* The PC-relative branch offset field on MIPS is 18 bits signed,
* so if the computed offset is larger than this we generate a an
* absolute jump that we skip with an inverted conditional branch.
*/
if (CONVERTED(*descp) || offset < -0x20000 || offset > 0x1ffff) {
offset = 3 * sizeof(u32);
op = invert_jmp(bpf_op);
ctx->changes += !CONVERTED(*descp);
*descp |= JIT_DESC_CONVERT;
}
done:
*jit_off = offset;
*jit_op = op;
}
/* Prepare a PC-relative jump operation with immediate conditional */
void setup_jmp_i(struct jit_context *ctx, s32 imm, u8 width,
u8 bpf_op, s16 bpf_off, u8 *jit_op, s32 *jit_off)
{
bool always = false;
bool never = false;
switch (bpf_op) {
case BPF_JEQ:
case BPF_JNE:
break;
case BPF_JSET:
case BPF_JLT:
never = imm == 0;
break;
case BPF_JGE:
always = imm == 0;
break;
case BPF_JGT:
never = (u32)imm == U32_MAX;
break;
case BPF_JLE:
always = (u32)imm == U32_MAX;
break;
case BPF_JSGT:
never = imm == S32_MAX && width == 32;
break;
case BPF_JSGE:
always = imm == S32_MIN && width == 32;
break;
case BPF_JSLT:
never = imm == S32_MIN && width == 32;
break;
case BPF_JSLE:
always = imm == S32_MAX && width == 32;
break;
}
if (never)
bpf_op = JIT_JNOP;
if (always)
bpf_op = BPF_JA;
setup_jmp(ctx, bpf_op, bpf_off, jit_op, jit_off);
}
/* Prepare a PC-relative jump operation with register conditional */
void setup_jmp_r(struct jit_context *ctx, bool same_reg,
u8 bpf_op, s16 bpf_off, u8 *jit_op, s32 *jit_off)
{
switch (bpf_op) {
case BPF_JSET:
break;
case BPF_JEQ:
case BPF_JGE:
case BPF_JLE:
case BPF_JSGE:
case BPF_JSLE:
if (same_reg)
bpf_op = BPF_JA;
break;
case BPF_JNE:
case BPF_JLT:
case BPF_JGT:
case BPF_JSGT:
case BPF_JSLT:
if (same_reg)
bpf_op = JIT_JNOP;
break;
}
setup_jmp(ctx, bpf_op, bpf_off, jit_op, jit_off);
}
/* Finish a PC-relative jump operation */
int finish_jmp(struct jit_context *ctx, u8 jit_op, s16 bpf_off)
{
/* Emit conditional branch delay slot */
if (jit_op != JIT_JNOP)
emit(ctx, nop);
/*
* Emit an absolute long jump with delay slot,
* if the PC-relative branch was converted.
*/
if (CONVERTED(ctx->descriptors[ctx->bpf_index])) {
int target = get_target(ctx, ctx->bpf_index + bpf_off + 1);
if (target < 0)
return -1;
emit(ctx, j, target);
emit(ctx, nop);
}
return 0;
}
/* Jump immediate (32-bit) */
void emit_jmp_i(struct jit_context *ctx, u8 dst, s32 imm, s32 off, u8 op)
{
switch (op) {
/* No-op, used internally for branch optimization */
case JIT_JNOP:
break;
/* PC += off if dst & imm */
case BPF_JSET:
emit(ctx, andi, MIPS_R_T9, dst, (u16)imm);
emit(ctx, bnez, MIPS_R_T9, off);
break;
/* PC += off if (dst & imm) == 0 (not in BPF, used for long jumps) */
case JIT_JNSET:
emit(ctx, andi, MIPS_R_T9, dst, (u16)imm);
emit(ctx, beqz, MIPS_R_T9, off);
break;
/* PC += off if dst > imm */
case BPF_JGT:
emit(ctx, sltiu, MIPS_R_T9, dst, imm + 1);
emit(ctx, beqz, MIPS_R_T9, off);
break;
/* PC += off if dst >= imm */
case BPF_JGE:
emit(ctx, sltiu, MIPS_R_T9, dst, imm);
emit(ctx, beqz, MIPS_R_T9, off);
break;
/* PC += off if dst < imm */
case BPF_JLT:
emit(ctx, sltiu, MIPS_R_T9, dst, imm);
emit(ctx, bnez, MIPS_R_T9, off);
break;
/* PC += off if dst <= imm */
case BPF_JLE:
emit(ctx, sltiu, MIPS_R_T9, dst, imm + 1);
emit(ctx, bnez, MIPS_R_T9, off);
break;
/* PC += off if dst > imm (signed) */
case BPF_JSGT:
emit(ctx, slti, MIPS_R_T9, dst, imm + 1);
emit(ctx, beqz, MIPS_R_T9, off);
break;
/* PC += off if dst >= imm (signed) */
case BPF_JSGE:
emit(ctx, slti, MIPS_R_T9, dst, imm);
emit(ctx, beqz, MIPS_R_T9, off);
break;
/* PC += off if dst < imm (signed) */
case BPF_JSLT:
emit(ctx, slti, MIPS_R_T9, dst, imm);
emit(ctx, bnez, MIPS_R_T9, off);
break;
/* PC += off if dst <= imm (signed) */
case BPF_JSLE:
emit(ctx, slti, MIPS_R_T9, dst, imm + 1);
emit(ctx, bnez, MIPS_R_T9, off);
break;
}
}
/* Jump register (32-bit) */
void emit_jmp_r(struct jit_context *ctx, u8 dst, u8 src, s32 off, u8 op)
{
switch (op) {
/* No-op, used internally for branch optimization */
case JIT_JNOP:
break;
/* PC += off if dst == src */
case BPF_JEQ:
emit(ctx, beq, dst, src, off);
break;
/* PC += off if dst != src */
case BPF_JNE:
emit(ctx, bne, dst, src, off);
break;
/* PC += off if dst & src */
case BPF_JSET:
emit(ctx, and, MIPS_R_T9, dst, src);
emit(ctx, bnez, MIPS_R_T9, off);
break;
/* PC += off if (dst & imm) == 0 (not in BPF, used for long jumps) */
case JIT_JNSET:
emit(ctx, and, MIPS_R_T9, dst, src);
emit(ctx, beqz, MIPS_R_T9, off);
break;
/* PC += off if dst > src */
case BPF_JGT:
emit(ctx, sltu, MIPS_R_T9, src, dst);
emit(ctx, bnez, MIPS_R_T9, off);
break;
/* PC += off if dst >= src */
case BPF_JGE:
emit(ctx, sltu, MIPS_R_T9, dst, src);
emit(ctx, beqz, MIPS_R_T9, off);
break;
/* PC += off if dst < src */
case BPF_JLT:
emit(ctx, sltu, MIPS_R_T9, dst, src);
emit(ctx, bnez, MIPS_R_T9, off);
break;
/* PC += off if dst <= src */
case BPF_JLE:
emit(ctx, sltu, MIPS_R_T9, src, dst);
emit(ctx, beqz, MIPS_R_T9, off);
break;
/* PC += off if dst > src (signed) */
case BPF_JSGT:
emit(ctx, slt, MIPS_R_T9, src, dst);
emit(ctx, bnez, MIPS_R_T9, off);
break;
/* PC += off if dst >= src (signed) */
case BPF_JSGE:
emit(ctx, slt, MIPS_R_T9, dst, src);
emit(ctx, beqz, MIPS_R_T9, off);
break;
/* PC += off if dst < src (signed) */
case BPF_JSLT:
emit(ctx, slt, MIPS_R_T9, dst, src);
emit(ctx, bnez, MIPS_R_T9, off);
break;
/* PC += off if dst <= src (signed) */
case BPF_JSLE:
emit(ctx, slt, MIPS_R_T9, src, dst);
emit(ctx, beqz, MIPS_R_T9, off);
break;
}
}
/* Jump always */
int emit_ja(struct jit_context *ctx, s16 off)
{
int target = get_target(ctx, ctx->bpf_index + off + 1);
if (target < 0)
return -1;
emit(ctx, j, target);
emit(ctx, nop);
return 0;
}
/* Jump to epilogue */
int emit_exit(struct jit_context *ctx)
{
int target = get_target(ctx, ctx->program->len);
if (target < 0)
return -1;
emit(ctx, j, target);
emit(ctx, nop);
return 0;
}
/* Build the program body from eBPF bytecode */
static int build_body(struct jit_context *ctx)
{
const struct bpf_prog *prog = ctx->program;
unsigned int i;
ctx->stack_used = 0;
for (i = 0; i < prog->len; i++) {
const struct bpf_insn *insn = &prog->insnsi[i];
u32 *descp = &ctx->descriptors[i];
int ret;
access_reg(ctx, insn->src_reg);
access_reg(ctx, insn->dst_reg);
ctx->bpf_index = i;
if (ctx->target == NULL) {
ctx->changes += INDEX(*descp) != ctx->jit_index;
*descp &= JIT_DESC_CONVERT;
*descp |= ctx->jit_index;
}
ret = build_insn(insn, ctx);
if (ret < 0)
return ret;
if (ret > 0) {
i++;
if (ctx->target == NULL)
descp[1] = ctx->jit_index;
}
}
/* Store the end offset, where the epilogue begins */
ctx->descriptors[prog->len] = ctx->jit_index;
return 0;
}
/* Set the branch conversion flag on all instructions */
static void set_convert_flag(struct jit_context *ctx, bool enable)
{
const struct bpf_prog *prog = ctx->program;
u32 flag = enable ? JIT_DESC_CONVERT : 0;
unsigned int i;
for (i = 0; i <= prog->len; i++)
ctx->descriptors[i] = INDEX(ctx->descriptors[i]) | flag;
}
static void jit_fill_hole(void *area, unsigned int size)
{
u32 *p;
/* We are guaranteed to have aligned memory. */
for (p = area; size >= sizeof(u32); size -= sizeof(u32))
uasm_i_break(&p, BRK_BUG); /* Increments p */
}
bool bpf_jit_needs_zext(void)
{
return true;
}
struct bpf_prog *bpf_int_jit_compile(struct bpf_prog *prog)
{
struct bpf_prog *tmp, *orig_prog = prog;
struct bpf_binary_header *header = NULL;
struct jit_context ctx;
bool tmp_blinded = false;
unsigned int tmp_idx;
unsigned int image_size;
u8 *image_ptr;
int tries;
/*
* If BPF JIT was not enabled then we must fall back to
* the interpreter.
*/
if (!prog->jit_requested)
return orig_prog;
/*
* If constant blinding was enabled and we failed during blinding
* then we must fall back to the interpreter. Otherwise, we save
* the new JITed code.
*/
tmp = bpf_jit_blind_constants(prog);
if (IS_ERR(tmp))
return orig_prog;
if (tmp != prog) {
tmp_blinded = true;
prog = tmp;
}
memset(&ctx, 0, sizeof(ctx));
ctx.program = prog;
/*
* Not able to allocate memory for descriptors[], then
* we must fall back to the interpreter
*/
ctx.descriptors = kcalloc(prog->len + 1, sizeof(*ctx.descriptors),
GFP_KERNEL);
if (ctx.descriptors == NULL)
goto out_err;
/* First pass discovers used resources */
if (build_body(&ctx) < 0)
goto out_err;
/*
* Second pass computes instruction offsets.
* If any PC-relative branches are out of range, a sequence of
* a PC-relative branch + a jump is generated, and we have to
* try again from the beginning to generate the new offsets.
* This is done until no additional conversions are necessary.
* The last two iterations are done with all branches being
* converted, to guarantee offset table convergence within a
* fixed number of iterations.
*/
ctx.jit_index = 0;
build_prologue(&ctx);
tmp_idx = ctx.jit_index;
tries = JIT_MAX_ITERATIONS;
do {
ctx.jit_index = tmp_idx;
ctx.changes = 0;
if (tries == 2)
set_convert_flag(&ctx, true);
if (build_body(&ctx) < 0)
goto out_err;
} while (ctx.changes > 0 && --tries > 0);
if (WARN_ONCE(ctx.changes > 0, "JIT offsets failed to converge"))
goto out_err;
build_epilogue(&ctx, MIPS_R_RA);
/* Now we know the size of the structure to make */
image_size = sizeof(u32) * ctx.jit_index;
header = bpf_jit_binary_alloc(image_size, &image_ptr,
sizeof(u32), jit_fill_hole);
/*
* Not able to allocate memory for the structure then
* we must fall back to the interpretation
*/
if (header == NULL)
goto out_err;
/* Actual pass to generate final JIT code */
ctx.target = (u32 *)image_ptr;
ctx.jit_index = 0;
/*
* If building the JITed code fails somehow,
* we fall back to the interpretation.
*/
build_prologue(&ctx);
if (build_body(&ctx) < 0)
goto out_err;
build_epilogue(&ctx, MIPS_R_RA);
/* Populate line info meta data */
set_convert_flag(&ctx, false);
bpf_prog_fill_jited_linfo(prog, &ctx.descriptors[1]);
/* Set as read-only exec and flush instruction cache */
bpf_jit_binary_lock_ro(header);
flush_icache_range((unsigned long)header,
(unsigned long)&ctx.target[ctx.jit_index]);
if (bpf_jit_enable > 1)
bpf_jit_dump(prog->len, image_size, 2, ctx.target);
prog->bpf_func = (void *)ctx.target;
prog->jited = 1;
prog->jited_len = image_size;
out:
if (tmp_blinded)
bpf_jit_prog_release_other(prog, prog == orig_prog ?
tmp : orig_prog);
kfree(ctx.descriptors);
return prog;
out_err:
prog = orig_prog;
if (header)
bpf_jit_binary_free(header);
goto out;
}