bpf_jit.h source code [linux/arch/parisc/net/bpf_jit.h]

1	/ SPDX-License-Identifier: GPL-2.0 /
2	/*
3	* Common functionality for PARISC32 and PARISC64 BPF JIT compilers
4	*
5	* Copyright (c) 2023 Helge Deller <deller@gmx.de>
6	*
7	*/
8
9	#ifndef _BPF_JIT_H
10	#define _BPF_JIT_H
11
12	#include <linux/bpf.h>
13	#include <linux/filter.h>
14	#include <asm/cacheflush.h>
15
16	#define HPPA_JIT_DEBUG 0
17	#define HPPA_JIT_REBOOT 0
18	#define HPPA_JIT_DUMP 0
19
20	#define OPTIMIZE_HPPA 1 /* enable some asm optimizations */
21	// echo 1 > /proc/sys/net/core/bpf_jit_enable
22
23	#define HPPA_R(nr) nr /* use HPPA register #nr */
24
25	enum {
26	HPPA_REG_ZERO = `0`, / The constant value 0 /
27	HPPA_REG_R1 = `1`, / used for addil /
28	HPPA_REG_RP = `2`, / Return address /
29
30	HPPA_REG_ARG7 = `19`, / ARG4-7 used in 64-bit ABI /
31	HPPA_REG_ARG6 = `20`,
32	HPPA_REG_ARG5 = `21`,
33	HPPA_REG_ARG4 = `22`,
34
35	HPPA_REG_ARG3 = `23`, / ARG0-3 in 32- and 64-bit ABI /
36	HPPA_REG_ARG2 = `24`,
37	HPPA_REG_ARG1 = `25`,
38	HPPA_REG_ARG0 = `26`,
39	HPPA_REG_GP = `27`, / Global pointer /
40	HPPA_REG_RET0 = `28`, / Return value, HI in 32-bit /
41	HPPA_REG_RET1 = `29`, / Return value, LOW in 32-bit /
42	HPPA_REG_SP = `30`, / Stack pointer /
43	HPPA_REG_R31 = `31`,
44
45	#ifdef CONFIG_64BIT
46	HPPA_REG_TCC = `3`,
47	HPPA_REG_TCC_SAVED = `4`,
48	HPPA_REG_TCC_IN_INIT = HPPA_REG_R31,
49	#else
50	HPPA_REG_TCC = `18`,
51	HPPA_REG_TCC_SAVED = `17`,
52	HPPA_REG_TCC_IN_INIT = HPPA_REG_R31,
53	#endif
54
55	HPPA_REG_T0 = HPPA_REG_R1, / Temporaries /
56	HPPA_REG_T1 = HPPA_REG_R31,
57	HPPA_REG_T2 = HPPA_REG_ARG4,
58	#ifndef CONFIG_64BIT
59	HPPA_REG_T3 = HPPA_REG_ARG5, / not used in 64-bit /
60	HPPA_REG_T4 = HPPA_REG_ARG6,
61	HPPA_REG_T5 = HPPA_REG_ARG7,
62	#endif
63	};
64
65	struct hppa_jit_context {
66	struct bpf_prog *prog;
67	u32 insns; /* HPPA insns /
68	int ninsns;
69	int reg_seen_collect;
70	int reg_seen;
71	int body_len;
72	int epilogue_offset;
73	int prologue_len;
74	int offset; /* BPF to HPPA /
75	};
76
77	#define REG_SET_SEEN(ctx, nr) { if (ctx->reg_seen_collect) ctx->reg_seen \|= BIT(nr); }
78	#define REG_SET_SEEN_ALL(ctx) { if (ctx->reg_seen_collect) ctx->reg_seen = -1; }
79	#define REG_FORCE_SEEN(ctx, nr) { ctx->reg_seen \|= BIT(nr); }
80	#define REG_WAS_SEEN(ctx, nr) (ctx->reg_seen & BIT(nr))
81	#define REG_ALL_SEEN(ctx) (ctx->reg_seen == -1)
82
83	#define HPPA_INSN_SIZE 4 /* bytes per HPPA asm instruction */
84	#define REG_SIZE REG_SZ /* bytes per native "long" word */
85
86	/ subtract hppa displacement on branches which is .+8 /
87	#define HPPA_BRANCH_DISPLACEMENT 2 /* instructions */
88
89	/ asm statement indicator to execute delay slot /
90	#define EXEC_NEXT_INSTR 0
91	#define NOP_NEXT_INSTR 1
92
93	#define im11(val) (((u32)(val)) & 0x07ff)
94
95	#define hppa_ldil(addr, reg) \
96	hppa_t5_insn(0x08, reg, ((u32)(addr)) >> 11) /* ldil im21,reg */
97	#define hppa_addil(addr, reg) \
98	hppa_t5_insn(0x0a, reg, ((u32)(addr)) >> 11) /* addil im21,reg -> result in gr1 */
99	#define hppa_ldo(im14, reg, target) \
100	hppa_t1_insn(0x0d, reg, target, im14) /* ldo val14(reg),target */
101	#define hppa_ldi(im14, reg) \
102	hppa_ldo(im14, HPPA_REG_ZERO, reg) /* ldi val14,reg */
103	#define hppa_or(reg1, reg2, target) \
104	hppa_t6_insn(0x02, reg2, reg1, 0, 0, 0x09, target) /* or reg1,reg2,target */
105	#define hppa_or_cond(reg1, reg2, cond, f, target) \
106	hppa_t6_insn(0x02, reg2, reg1, cond, f, 0x09, target)
107	#define hppa_and(reg1, reg2, target) \
108	hppa_t6_insn(0x02, reg2, reg1, 0, 0, 0x08, target) /* and reg1,reg2,target */
109	#define hppa_and_cond(reg1, reg2, cond, f, target) \
110	hppa_t6_insn(0x02, reg2, reg1, cond, f, 0x08, target)
111	#define hppa_xor(reg1, reg2, target) \
112	hppa_t6_insn(0x02, reg2, reg1, 0, 0, 0x0a, target) /* xor reg1,reg2,target */
113	#define hppa_add(reg1, reg2, target) \
114	hppa_t6_insn(0x02, reg2, reg1, 0, 0, 0x18, target) /* add reg1,reg2,target */
115	#define hppa_addc(reg1, reg2, target) \
116	hppa_t6_insn(0x02, reg2, reg1, 0, 0, 0x1c, target) /* add,c reg1,reg2,target */
117	#define hppa_sub(reg1, reg2, target) \
118	hppa_t6_insn(0x02, reg2, reg1, 0, 0, 0x10, target) /* sub reg1,reg2,target */
119	#define hppa_subb(reg1, reg2, target) \
120	hppa_t6_insn(0x02, reg2, reg1, 0, 0, 0x14, target) /* sub,b reg1,reg2,target */
121	#define hppa_nop() \
122	hppa_or(0,0,0) /* nop: or 0,0,0 */
123	#define hppa_addi(val11, reg, target) \
124	hppa_t7_insn(0x2d, reg, target, val11) /* addi im11,reg,target */
125	#define hppa_subi(val11, reg, target) \
126	hppa_t7_insn(0x25, reg, target, val11) /* subi im11,reg,target */
127	#define hppa_copy(reg, target) \
128	hppa_or(reg, HPPA_REG_ZERO, target) /* copy reg,target */
129	#define hppa_ldw(val14, reg, target) \
130	hppa_t1_insn(0x12, reg, target, val14) /* ldw im14(reg),target */
131	#define hppa_ldb(val14, reg, target) \
132	hppa_t1_insn(0x10, reg, target, val14) /* ldb im14(reg),target */
133	#define hppa_ldh(val14, reg, target) \
134	hppa_t1_insn(0x11, reg, target, val14) /* ldh im14(reg),target */
135	#define hppa_stw(reg, val14, base) \
136	hppa_t1_insn(0x1a, base, reg, val14) /* stw reg,im14(base) */
137	#define hppa_stb(reg, val14, base) \
138	hppa_t1_insn(0x18, base, reg, val14) /* stb reg,im14(base) */
139	#define hppa_sth(reg, val14, base) \
140	hppa_t1_insn(0x19, base, reg, val14) /* sth reg,im14(base) */
141	#define hppa_stwma(reg, val14, base) \
142	hppa_t1_insn(0x1b, base, reg, val14) /* stw,ma reg,im14(base) */
143	#define hppa_bv(reg, base, nop) \
144	hppa_t11_insn(0x3a, base, reg, 0x06, 0, nop) /* bv(,n) reg(base) */
145	#define hppa_be(offset, base) \
146	hppa_t12_insn(0x38, base, offset, 0x00, 1) /* be,n offset(0,base) */
147	#define hppa_be_l(offset, base, nop) \
148	hppa_t12_insn(0x39, base, offset, 0x00, nop) /* ble(,nop) offset(0,base) */
149	#define hppa_mtctl(reg, cr) \
150	hppa_t21_insn(0x00, cr, reg, 0xc2, 0) /* mtctl reg,cr */
151	#define hppa_mtsar(reg) \
152	hppa_mtctl(reg, 11) /* mtsar reg */
153	#define hppa_zdep(r, p, len, target) \
154	hppa_t10_insn(0x35, target, r, 0, 2, p, len) /* zdep r,a,b,t */
155	#define hppa_shl(r, len, target) \
156	hppa_zdep(r, len, len, lo(rd))
157	#define hppa_depwz(r, p, len, target) \
158	hppa_t10_insn(0x35, target, r, 0, 3, 31-(p), 32-(len)) /* depw,z r,p,len,ret1 */
159	#define hppa_depwz_sar(reg, target) \
160	hppa_t1_insn(0x35, target, reg, 0) /* depw,z reg,sar,32,target */
161	#define hppa_shrpw_sar(reg, target) \
162	hppa_t10_insn(0x34, reg, 0, 0, 0, 0, target) /* shrpw r0,reg,sar,target */
163	#define hppa_shrpw(r1, r2, p, target) \
164	hppa_t10_insn(0x34, r2, r1, 0, 2, 31-(p), target) /* shrpw r1,r2,p,target */
165	#define hppa_shd(r1, r2, p, target) \
166	hppa_t10_insn(0x34, r2, r1, 0, 2, 31-(p), target) /* shrpw r1,r2,p,tarfer */
167	#define hppa_extrws_sar(reg, target) \
168	hppa_t10_insn(0x34, reg, target, 0, 5, 0, 0) /* extrw,s reg,sar,32,ret0 */
169	#define hppa_extrws(reg, p, len, target) \
170	hppa_t10_insn(0x34, reg, target, 0, 7, p, len) /* extrw,s reg,p,len,target */
171	#define hppa_extru(r, p, len, target) \
172	hppa_t10_insn(0x34, r, target, 0, 6, p, 32-(len))
173	#define hppa_shr(r, len, target) \
174	hppa_extru(r, 31-(len), 32-(len), target)
175	#define hppa_bl(imm17, rp) \
176	hppa_t12_insn(0x3a, rp, imm17, 0x00, 1) /* bl,n target_addr,rp */
177	#define hppa_sh2add(r1, r2, target) \
178	hppa_t6_insn(0x02, r2, r1, 0, 0, 0x1a, target) /* sh2add r1,r2,target */
179
180	#define hppa_combt(r1, r2, target_addr, condition, nop) \
181	hppa_t11_insn(IS_ENABLED(CONFIG_64BIT) ? 0x27 : 0x20, \
182	r2, r1, condition, target_addr, nop) /* combt,cond,n r1,r2,addr */
183	#define hppa_beq(r1, r2, target_addr) \
184	hppa_combt(r1, r2, target_addr, 1, NOP_NEXT_INSTR)
185	#define hppa_blt(r1, r2, target_addr) \
186	hppa_combt(r1, r2, target_addr, 2, NOP_NEXT_INSTR)
187	#define hppa_ble(r1, r2, target_addr) \
188	hppa_combt(r1, r2, target_addr, 3, NOP_NEXT_INSTR)
189	#define hppa_bltu(r1, r2, target_addr) \
190	hppa_combt(r1, r2, target_addr, 4, NOP_NEXT_INSTR)
191	#define hppa_bleu(r1, r2, target_addr) \
192	hppa_combt(r1, r2, target_addr, 5, NOP_NEXT_INSTR)
193
194	#define hppa_combf(r1, r2, target_addr, condition, nop) \
195	hppa_t11_insn(IS_ENABLED(CONFIG_64BIT) ? 0x2f : 0x22, \
196	r2, r1, condition, target_addr, nop) /* combf,cond,n r1,r2,addr */
197	#define hppa_bne(r1, r2, target_addr) \
198	hppa_combf(r1, r2, target_addr, 1, NOP_NEXT_INSTR)
199	#define hppa_bge(r1, r2, target_addr) \
200	hppa_combf(r1, r2, target_addr, 2, NOP_NEXT_INSTR)
201	#define hppa_bgt(r1, r2, target_addr) \
202	hppa_combf(r1, r2, target_addr, 3, NOP_NEXT_INSTR)
203	#define hppa_bgeu(r1, r2, target_addr) \
204	hppa_combf(r1, r2, target_addr, 4, NOP_NEXT_INSTR)
205	#define hppa_bgtu(r1, r2, target_addr) \
206	hppa_combf(r1, r2, target_addr, 5, NOP_NEXT_INSTR)
207
208	/ 64-bit instructions /
209	#ifdef CONFIG_64BIT
210	#define hppa64_ldd_reg(reg, b, target) \
211	hppa_t10_insn(0x03, b, reg, 0, 0, 3<<1, target)
212	#define hppa64_ldd_im5(im5, b, target) \
213	hppa_t10_insn(0x03, b, low_sign_unext(im5,5), 0, 1<<2, 3<<1, target)
214	#define hppa64_ldd_im16(im16, b, target) \
215	hppa_t10_insn(0x14, b, target, 0, 0, 0, 0) \| re_assemble_16(im16)
216	#define hppa64_std_im5(src, im5, b) \
217	hppa_t10_insn(0x03, b, src, 0, 1<<2, 0xB<<1, low_sign_unext(im5,5))
218	#define hppa64_std_im16(src, im16, b) \
219	hppa_t10_insn(0x1c, b, src, 0, 0, 0, 0) \| re_assemble_16(im16)
220	#define hppa64_bl_long(offs22) \
221	hppa_t12_L_insn(0x3a, offs22, 1)
222	#define hppa64_mtsarcm(reg) \
223	hppa_t21_insn(0x00, 11, reg, 0xc6, 0)
224	#define hppa64_shrpd_sar(reg, target) \
225	hppa_t10_insn(0x34, reg, 0, 0, 0, 1<<4, target)
226	#define hppa64_shladd(r1, sa, r2, target) \
227	hppa_t6_insn(0x02, r2, r1, 0, 0, 1<<4\|1<<3\|sa, target)
228	#define hppa64_depdz_sar(reg, target) \
229	hppa_t21_insn(0x35, target, reg, 3<<3, 0)
230	#define hppa_extrd_sar(reg, target, se) \
231	hppa_t10_insn(0x34, reg, target, 0, 0, 0, 0) \| 2<<11 \| (se&1)<<10 \| 1<<9 \| 1<<8
232	#define hppa64_bve_l_rp(base) \
233	(0x3a << 26) \| (base << 21) \| 0xf000
234	#define hppa64_permh_3210(r, target) \
235	(0x3e << 26) \| (r << 21) \| (r << 16) \| (target) \| 0x00006900
236	#define hppa64_hshl(r, sa, target) \
237	(0x3e << 26) \| (0 << 21) \| (r << 16) \| (sa << 6) \| (target) \| 0x00008800
238	#define hppa64_hshr_u(r, sa, target) \
239	(0x3e << 26) \| (r << 21) \| (0 << 16) \| (sa << 6) \| (target) \| 0x0000c800
240	#endif
241
242	struct hppa_jit_data {
243	struct bpf_binary_header *header;
244	u8 *image;
245	struct hppa_jit_context ctx;
246	};
247
248	static inline void bpf_fill_ill_insns(void area, unsigned* int size)
249	{
250	memset(area, `0`, size);
251	}
252
253	static inline void bpf_flush_icache(void start, void* *end)
254	{
255	flush_icache_range(start: (unsigned long)start, end: (unsigned long)end);
256	}
257
258	/ Emit a 4-byte HPPA instruction. /
259	static inline void emit(const u32 insn, struct hppa_jit_context *ctx)
260	{
261	if (ctx->insns) {
262	ctx->insns[ctx->ninsns] = insn;
263	}
264
265	ctx->ninsns++;
266	}
267
268	static inline int epilogue_offset(struct hppa_jit_context *ctx)
269	{
270	int to = ctx->epilogue_offset, from = ctx->ninsns;
271
272	return (to - from);
273	}
274
275	/ Return -1 or inverted cond. /
276	static inline int invert_bpf_cond(u8 cond)
277	{
278	switch (cond) {
279	case BPF_JEQ:
280	return BPF_JNE;
281	case BPF_JGT:
282	return BPF_JLE;
283	case BPF_JLT:
284	return BPF_JGE;
285	case BPF_JGE:
286	return BPF_JLT;
287	case BPF_JLE:
288	return BPF_JGT;
289	case BPF_JNE:
290	return BPF_JEQ;
291	case BPF_JSGT:
292	return BPF_JSLE;
293	case BPF_JSLT:
294	return BPF_JSGE;
295	case BPF_JSGE:
296	return BPF_JSLT;
297	case BPF_JSLE:
298	return BPF_JSGT;
299	}
300	return -`1`;
301	}
302
303
304	static inline signed long hppa_offset(int insn, int off, struct hppa_jit_context *ctx)
305	{
306	signed long from, to;
307
308	off++; / BPF branch is from PC+1 /
309	from = (insn > `0`) ? ctx->offset[insn - `1`] : `0`;
310	to = (insn + off > `0`) ? ctx->offset[insn + off - `1`] : `0`;
311	return (to - from);
312	}
313
314	/ does the signed value fits into a given number of bits ? /
315	static inline int check_bits_int(signed long val, int bits)
316	{
317	return ((val >= `0`) && ((val >> bits) == `0`)) \|\|
318	((val < `0`) && (((~((u32)val)) >> (bits-`1`)) == `0`));
319	}
320
321	/ can the signed value be used in relative code ? /
322	static inline int relative_bits_ok(signed long val, int bits)
323	{
324	return ((val >= `0`) && (val < (`1UL` << (bits-`1`)))) \|\| / XXX /
325	((val < `0`) && (((~((unsigned long)val)) >> (bits-`1`)) == `0`)
326	&& (val & (`1UL` << (bits-`1`))));
327	}
328
329	/ can the signed value be used in relative branches ? /
330	static inline int relative_branch_ok(signed long val, int bits)
331	{
332	return ((val >= `0`) && (val < (`1UL` << (bits-`2`)))) \|\| / XXX /
333	((val < `0`) && (((~((unsigned long)val)) < (`1UL` << (bits-`2`))))
334	&& (val & (`1UL` << (bits-`1`))));
335	}
336
337
338	#define is_5b_int(val) check_bits_int(val, 5)
339
340	static inline unsigned sign_unext(unsigned x, unsigned len)
341	{
342	unsigned len_ones;
343
344	len_ones = (`1` << len) - `1`;
345	return x & len_ones;
346	}
347
348	static inline unsigned low_sign_unext(unsigned x, unsigned len)
349	{
350	unsigned temp;
351	unsigned sign;
352
353	sign = (x >> (len-`1`)) & `1`;
354	temp = sign_unext (x, len: len-`1`);
355	return (temp << `1`) \| sign;
356	}
357
358	static inline unsigned re_assemble_12(unsigned as12)
359	{
360	return (( (as12 & `0x800`) >> `11`)
361	\| ((as12 & `0x400`) >> (`10` - `2`))
362	\| ((as12 & `0x3ff`) << (`1` + `2`)));
363	}
364
365	static inline unsigned re_assemble_14(unsigned as14)
366	{
367	return (( (as14 & `0x1fff`) << `1`)
368	\| ((as14 & `0x2000`) >> `13`));
369	}
370
371	#ifdef CONFIG_64BIT
372	static inline unsigned re_assemble_16(unsigned as16)
373	{
374	unsigned s, t;
375
376	/ Unusual 16-bit encoding, for wide mode only. /
377	t = (as16 << `1`) & `0xffff`;
378	s = (as16 & `0x8000`);
379	return (t ^ s ^ (s >> `1`)) \| (s >> `15`);
380	}
381	#endif
382
383	static inline unsigned re_assemble_17(unsigned as17)
384	{
385	return (( (as17 & `0x10000`) >> `16`)
386	\| ((as17 & `0x0f800`) << (`16` - `11`))
387	\| ((as17 & `0x00400`) >> (`10` - `2`))
388	\| ((as17 & `0x003ff`) << (`1` + `2`)));
389	}
390
391	static inline unsigned re_assemble_21(unsigned as21)
392	{
393	return (( (as21 & `0x100000`) >> `20`)
394	\| ((as21 & `0x0ffe00`) >> `8`)
395	\| ((as21 & `0x000180`) << `7`)
396	\| ((as21 & `0x00007c`) << `14`)
397	\| ((as21 & `0x000003`) << `12`));
398	}
399
400	static inline unsigned re_assemble_22(unsigned as22)
401	{
402	return (( (as22 & `0x200000`) >> `21`)
403	\| ((as22 & `0x1f0000`) << (`21` - `16`))
404	\| ((as22 & `0x00f800`) << (`16` - `11`))
405	\| ((as22 & `0x000400`) >> (`10` - `2`))
406	\| ((as22 & `0x0003ff`) << (`1` + `2`)));
407	}
408
409	/ Various HPPA instruction formats. /
410	/ see https://parisc.wiki.kernel.org/images-parisc/6/68/Pa11_acd.pdf, appendix C /
411
412	static inline u32 hppa_t1_insn(u8 opcode, u8 b, u8 r, s16 im14)
413	{
414	return ((opcode << `26`) \| (b << `21`) \| (r << `16`) \| re_assemble_14(as14: im14));
415	}
416
417	static inline u32 hppa_t5_insn(u8 opcode, u8 tr, u32 val21)
418	{
419	return ((opcode << `26`) \| (tr << `21`) \| re_assemble_21(as21: val21));
420	}
421
422	static inline u32 hppa_t6_insn(u8 opcode, u8 r2, u8 r1, u8 c, u8 f, u8 ext6, u16 t)
423	{
424	return ((opcode << `26`) \| (r2 << `21`) \| (r1 << `16`) \| (c << `13`) \| (f << `12`) \|
425	(ext6 << `6`) \| t);
426	}
427
428	/ 7. Arithmetic immediate /
429	static inline u32 hppa_t7_insn(u8 opcode, u8 r, u8 t, u32 im11)
430	{
431	return ((opcode << `26`) \| (r << `21`) \| (t << `16`) \| low_sign_unext(x: im11, len: `11`));
432	}
433
434	/ 10. Shift instructions /
435	static inline u32 hppa_t10_insn(u8 opcode, u8 r2, u8 r1, u8 c, u8 ext3, u8 cp, u8 t)
436	{
437	return ((opcode << `26`) \| (r2 << `21`) \| (r1 << `16`) \| (c << `13`) \|
438	(ext3 << `10`) \| (cp << `5`) \| t);
439	}
440
441	/ 11. Conditional branch instructions /
442	static inline u32 hppa_t11_insn(u8 opcode, u8 r2, u8 r1, u8 c, u32 w, u8 nop)
443	{
444	u32 ra = re_assemble_12(as12: w);
445	// ra = low_sign_unext(w,11) \| (w & (1<<10)
446	return ((opcode << `26`) \| (r2 << `21`) \| (r1 << `16`) \| (c << `13`) \| (nop << `1`) \| ra);
447	}
448
449	/ 12. Branch instructions /
450	static inline u32 hppa_t12_insn(u8 opcode, u8 rp, u32 w, u8 ext3, u8 nop)
451	{
452	return ((opcode << `26`) \| (rp << `21`) \| (ext3 << `13`) \| (nop << `1`) \| re_assemble_17(as17: w));
453	}
454
455	static inline u32 hppa_t12_L_insn(u8 opcode, u32 w, u8 nop)
456	{
457	return ((opcode << `26`) \| (`0x05` << `13`) \| (nop << `1`) \| re_assemble_22(as22: w));
458	}
459
460	/ 21. Move to control register /
461	static inline u32 hppa_t21_insn(u8 opcode, u8 r2, u8 r1, u8 ext8, u8 t)
462	{
463	return ((opcode << `26`) \| (r2 << `21`) \| (r1 << `16`) \| (ext8 << `5`) \| t);
464	}
465
466	/ Helper functions called by jit code on HPPA32 and HPPA64. /
467
468	u64 hppa_div64(u64 div, u64 divisor);
469	u64 hppa_div64_rem(u64 div, u64 divisor);
470
471	/ Helper functions that emit HPPA instructions when possible. /
472
473	void bpf_jit_build_prologue(struct hppa_jit_context *ctx);
474	void bpf_jit_build_epilogue(struct hppa_jit_context *ctx);
475
476	int bpf_jit_emit_insn(const struct bpf_insn insn, struct* hppa_jit_context *ctx,
477	bool extra_pass);
478
479	#endif /* _BPF_JIT_H */
480

source code of linux/arch/parisc/net/bpf_jit.h