linuxdebug/tools/testing/selftests/bpf/progs/strobemeta.h

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2024-07-16 15:50:57 +02:00
// SPDX-License-Identifier: GPL-2.0
// Copyright (c) 2019 Facebook
#include <stdint.h>
#include <stddef.h>
#include <stdbool.h>
#include <linux/bpf.h>
#include <linux/ptrace.h>
#include <linux/sched.h>
#include <linux/types.h>
#include <bpf/bpf_helpers.h>
typedef uint32_t pid_t;
struct task_struct {};
#define TASK_COMM_LEN 16
#define PERF_MAX_STACK_DEPTH 127
#define STROBE_TYPE_INVALID 0
#define STROBE_TYPE_INT 1
#define STROBE_TYPE_STR 2
#define STROBE_TYPE_MAP 3
#define STACK_TABLE_EPOCH_SHIFT 20
#define STROBE_MAX_STR_LEN 1
#define STROBE_MAX_CFGS 32
#define STROBE_MAX_PAYLOAD \
(STROBE_MAX_STRS * STROBE_MAX_STR_LEN + \
STROBE_MAX_MAPS * (1 + STROBE_MAX_MAP_ENTRIES * 2) * STROBE_MAX_STR_LEN)
struct strobe_value_header {
/*
* meaning depends on type:
* 1. int: 0, if value not set, 1 otherwise
* 2. str: 1 always, whether value is set or not is determined by ptr
* 3. map: 1 always, pointer points to additional struct with number
* of entries (up to STROBE_MAX_MAP_ENTRIES)
*/
uint16_t len;
/*
* _reserved might be used for some future fields/flags, but we always
* want to keep strobe_value_header to be 8 bytes, so BPF can read 16
* bytes in one go and get both header and value
*/
uint8_t _reserved[6];
};
/*
* strobe_value_generic is used from BPF probe only, but needs to be a union
* of strobe_value_int/strobe_value_str/strobe_value_map
*/
struct strobe_value_generic {
struct strobe_value_header header;
union {
int64_t val;
void *ptr;
};
};
struct strobe_value_int {
struct strobe_value_header header;
int64_t value;
};
struct strobe_value_str {
struct strobe_value_header header;
const char* value;
};
struct strobe_value_map {
struct strobe_value_header header;
const struct strobe_map_raw* value;
};
struct strobe_map_entry {
const char* key;
const char* val;
};
/*
* Map of C-string key/value pairs with fixed maximum capacity. Each map has
* corresponding int64 ID, which application can use (or ignore) in whatever
* way appropriate. Map is "write-only", there is no way to get data out of
* map. Map is intended to be used to provide metadata for profilers and is
* not to be used for internal in-app communication. All methods are
* thread-safe.
*/
struct strobe_map_raw {
/*
* general purpose unique ID that's up to application to decide
* whether and how to use; for request metadata use case id is unique
* request ID that's used to match metadata with stack traces on
* Strobelight backend side
*/
int64_t id;
/* number of used entries in map */
int64_t cnt;
/*
* having volatile doesn't change anything on BPF side, but clang
* emits warnings for passing `volatile const char *` into
* bpf_probe_read_user_str that expects just `const char *`
*/
const char* tag;
/*
* key/value entries, each consisting of 2 pointers to key and value
* C strings
*/
struct strobe_map_entry entries[STROBE_MAX_MAP_ENTRIES];
};
/* Following values define supported values of TLS mode */
#define TLS_NOT_SET -1
#define TLS_LOCAL_EXEC 0
#define TLS_IMM_EXEC 1
#define TLS_GENERAL_DYN 2
/*
* structure that universally represents TLS location (both for static
* executables and shared libraries)
*/
struct strobe_value_loc {
/*
* tls_mode defines what TLS mode was used for particular metavariable:
* - -1 (TLS_NOT_SET) - no metavariable;
* - 0 (TLS_LOCAL_EXEC) - Local Executable mode;
* - 1 (TLS_IMM_EXEC) - Immediate Executable mode;
* - 2 (TLS_GENERAL_DYN) - General Dynamic mode;
* Local Dynamic mode is not yet supported, because never seen in
* practice. Mode defines how offset field is interpreted. See
* calc_location() in below for details.
*/
int64_t tls_mode;
/*
* TLS_LOCAL_EXEC: offset from thread pointer (fs:0 for x86-64,
* tpidr_el0 for aarch64).
* TLS_IMM_EXEC: absolute address of GOT entry containing offset
* from thread pointer;
* TLS_GENERAL_DYN: absolute addres of double GOT entry
* containing tls_index_t struct;
*/
int64_t offset;
};
struct strobemeta_cfg {
int64_t req_meta_idx;
struct strobe_value_loc int_locs[STROBE_MAX_INTS];
struct strobe_value_loc str_locs[STROBE_MAX_STRS];
struct strobe_value_loc map_locs[STROBE_MAX_MAPS];
};
struct strobe_map_descr {
uint64_t id;
int16_t tag_len;
/*
* cnt <0 - map value isn't set;
* 0 - map has id set, but no key/value entries
*/
int16_t cnt;
/*
* both key_lens[i] and val_lens[i] should be >0 for present key/value
* entry
*/
uint16_t key_lens[STROBE_MAX_MAP_ENTRIES];
uint16_t val_lens[STROBE_MAX_MAP_ENTRIES];
};
struct strobemeta_payload {
/* req_id has valid request ID, if req_meta_valid == 1 */
int64_t req_id;
uint8_t req_meta_valid;
/*
* mask has Nth bit set to 1, if Nth metavar was present and
* successfully read
*/
uint64_t int_vals_set_mask;
int64_t int_vals[STROBE_MAX_INTS];
/* len is >0 for present values */
uint16_t str_lens[STROBE_MAX_STRS];
/* if map_descrs[i].cnt == -1, metavar is not present/set */
struct strobe_map_descr map_descrs[STROBE_MAX_MAPS];
/*
* payload has compactly packed values of str and map variables in the
* form: strval1\0strval2\0map1key1\0map1val1\0map2key1\0map2val1\0
* (and so on); str_lens[i], key_lens[i] and val_lens[i] determines
* value length
*/
char payload[STROBE_MAX_PAYLOAD];
};
struct strobelight_bpf_sample {
uint64_t ktime;
char comm[TASK_COMM_LEN];
pid_t pid;
int user_stack_id;
int kernel_stack_id;
int has_meta;
struct strobemeta_payload metadata;
/*
* makes it possible to pass (<real payload size> + 1) as data size to
* perf_submit() to avoid perf_submit's paranoia about passing zero as
* size, as it deduces that <real payload size> might be
* **theoretically** zero
*/
char dummy_safeguard;
};
struct {
__uint(type, BPF_MAP_TYPE_PERF_EVENT_ARRAY);
__uint(max_entries, 32);
__uint(key_size, sizeof(int));
__uint(value_size, sizeof(int));
} samples SEC(".maps");
struct {
__uint(type, BPF_MAP_TYPE_STACK_TRACE);
__uint(max_entries, 16);
__uint(key_size, sizeof(uint32_t));
__uint(value_size, sizeof(uint64_t) * PERF_MAX_STACK_DEPTH);
} stacks_0 SEC(".maps");
struct {
__uint(type, BPF_MAP_TYPE_STACK_TRACE);
__uint(max_entries, 16);
__uint(key_size, sizeof(uint32_t));
__uint(value_size, sizeof(uint64_t) * PERF_MAX_STACK_DEPTH);
} stacks_1 SEC(".maps");
struct {
__uint(type, BPF_MAP_TYPE_PERCPU_ARRAY);
__uint(max_entries, 1);
__type(key, uint32_t);
__type(value, struct strobelight_bpf_sample);
} sample_heap SEC(".maps");
struct {
__uint(type, BPF_MAP_TYPE_PERCPU_ARRAY);
__uint(max_entries, STROBE_MAX_CFGS);
__type(key, pid_t);
__type(value, struct strobemeta_cfg);
} strobemeta_cfgs SEC(".maps");
/* Type for the dtv. */
/* https://github.com/lattera/glibc/blob/master/nptl/sysdeps/x86_64/tls.h#L34 */
typedef union dtv {
size_t counter;
struct {
void* val;
bool is_static;
} pointer;
} dtv_t;
/* Partial definition for tcbhead_t */
/* https://github.com/bminor/glibc/blob/master/sysdeps/x86_64/nptl/tls.h#L42 */
struct tcbhead {
void* tcb;
dtv_t* dtv;
};
/*
* TLS module/offset information for shared library case.
* For x86-64, this is mapped onto two entries in GOT.
* For aarch64, this is pointed to by second GOT entry.
*/
struct tls_index {
uint64_t module;
uint64_t offset;
};
#ifdef SUBPROGS
__noinline
#else
__always_inline
#endif
static void *calc_location(struct strobe_value_loc *loc, void *tls_base)
{
/*
* tls_mode value is:
* - -1 (TLS_NOT_SET), if no metavar is present;
* - 0 (TLS_LOCAL_EXEC), if metavar uses Local Executable mode of TLS
* (offset from fs:0 for x86-64 or tpidr_el0 for aarch64);
* - 1 (TLS_IMM_EXEC), if metavar uses Immediate Executable mode of TLS;
* - 2 (TLS_GENERAL_DYN), if metavar uses General Dynamic mode of TLS;
* This schema allows to use something like:
* (tls_mode + 1) * (tls_base + offset)
* to get NULL for "no metavar" location, or correct pointer for local
* executable mode without doing extra ifs.
*/
if (loc->tls_mode <= TLS_LOCAL_EXEC) {
/* static executable is simple, we just have offset from
* tls_base */
void *addr = tls_base + loc->offset;
/* multiply by (tls_mode + 1) to get NULL, if we have no
* metavar in this slot */
return (void *)((loc->tls_mode + 1) * (int64_t)addr);
}
/*
* Other modes are more complicated, we need to jump through few hoops.
*
* For immediate executable mode (currently supported only for aarch64):
* - loc->offset is pointing to a GOT entry containing fixed offset
* relative to tls_base;
*
* For general dynamic mode:
* - loc->offset is pointing to a beginning of double GOT entries;
* - (for aarch64 only) second entry points to tls_index_t struct;
* - (for x86-64 only) two GOT entries are already tls_index_t;
* - tls_index_t->module is used to find start of TLS section in
* which variable resides;
* - tls_index_t->offset provides offset within that TLS section,
* pointing to value of variable.
*/
struct tls_index tls_index;
dtv_t *dtv;
void *tls_ptr;
bpf_probe_read_user(&tls_index, sizeof(struct tls_index),
(void *)loc->offset);
/* valid module index is always positive */
if (tls_index.module > 0) {
/* dtv = ((struct tcbhead *)tls_base)->dtv[tls_index.module] */
bpf_probe_read_user(&dtv, sizeof(dtv),
&((struct tcbhead *)tls_base)->dtv);
dtv += tls_index.module;
} else {
dtv = NULL;
}
bpf_probe_read_user(&tls_ptr, sizeof(void *), dtv);
/* if pointer has (void *)-1 value, then TLS wasn't initialized yet */
return tls_ptr && tls_ptr != (void *)-1
? tls_ptr + tls_index.offset
: NULL;
}
#ifdef SUBPROGS
__noinline
#else
__always_inline
#endif
static void read_int_var(struct strobemeta_cfg *cfg,
size_t idx, void *tls_base,
struct strobe_value_generic *value,
struct strobemeta_payload *data)
{
void *location = calc_location(&cfg->int_locs[idx], tls_base);
if (!location)
return;
bpf_probe_read_user(value, sizeof(struct strobe_value_generic), location);
data->int_vals[idx] = value->val;
if (value->header.len)
data->int_vals_set_mask |= (1 << idx);
}
static __always_inline uint64_t read_str_var(struct strobemeta_cfg *cfg,
size_t idx, void *tls_base,
struct strobe_value_generic *value,
struct strobemeta_payload *data,
void *payload)
{
void *location;
uint64_t len;
data->str_lens[idx] = 0;
location = calc_location(&cfg->str_locs[idx], tls_base);
if (!location)
return 0;
bpf_probe_read_user(value, sizeof(struct strobe_value_generic), location);
len = bpf_probe_read_user_str(payload, STROBE_MAX_STR_LEN, value->ptr);
/*
* if bpf_probe_read_user_str returns error (<0), due to casting to
* unsinged int, it will become big number, so next check is
* sufficient to check for errors AND prove to BPF verifier, that
* bpf_probe_read_user_str won't return anything bigger than
* STROBE_MAX_STR_LEN
*/
if (len > STROBE_MAX_STR_LEN)
return 0;
data->str_lens[idx] = len;
return len;
}
static __always_inline void *read_map_var(struct strobemeta_cfg *cfg,
size_t idx, void *tls_base,
struct strobe_value_generic *value,
struct strobemeta_payload *data,
void *payload)
{
struct strobe_map_descr* descr = &data->map_descrs[idx];
struct strobe_map_raw map;
void *location;
uint64_t len;
int i;
descr->tag_len = 0; /* presume no tag is set */
descr->cnt = -1; /* presume no value is set */
location = calc_location(&cfg->map_locs[idx], tls_base);
if (!location)
return payload;
bpf_probe_read_user(value, sizeof(struct strobe_value_generic), location);
if (bpf_probe_read_user(&map, sizeof(struct strobe_map_raw), value->ptr))
return payload;
descr->id = map.id;
descr->cnt = map.cnt;
if (cfg->req_meta_idx == idx) {
data->req_id = map.id;
data->req_meta_valid = 1;
}
len = bpf_probe_read_user_str(payload, STROBE_MAX_STR_LEN, map.tag);
if (len <= STROBE_MAX_STR_LEN) {
descr->tag_len = len;
payload += len;
}
#ifdef NO_UNROLL
#pragma clang loop unroll(disable)
#else
#pragma unroll
#endif
for (int i = 0; i < STROBE_MAX_MAP_ENTRIES; ++i) {
if (i >= map.cnt)
break;
descr->key_lens[i] = 0;
len = bpf_probe_read_user_str(payload, STROBE_MAX_STR_LEN,
map.entries[i].key);
if (len <= STROBE_MAX_STR_LEN) {
descr->key_lens[i] = len;
payload += len;
}
descr->val_lens[i] = 0;
len = bpf_probe_read_user_str(payload, STROBE_MAX_STR_LEN,
map.entries[i].val);
if (len <= STROBE_MAX_STR_LEN) {
descr->val_lens[i] = len;
payload += len;
}
}
return payload;
}
#ifdef USE_BPF_LOOP
enum read_type {
READ_INT_VAR,
READ_MAP_VAR,
READ_STR_VAR,
};
struct read_var_ctx {
struct strobemeta_payload *data;
void *tls_base;
struct strobemeta_cfg *cfg;
void *payload;
/* value gets mutated */
struct strobe_value_generic *value;
enum read_type type;
};
static int read_var_callback(__u32 index, struct read_var_ctx *ctx)
{
switch (ctx->type) {
case READ_INT_VAR:
if (index >= STROBE_MAX_INTS)
return 1;
read_int_var(ctx->cfg, index, ctx->tls_base, ctx->value, ctx->data);
break;
case READ_MAP_VAR:
if (index >= STROBE_MAX_MAPS)
return 1;
ctx->payload = read_map_var(ctx->cfg, index, ctx->tls_base,
ctx->value, ctx->data, ctx->payload);
break;
case READ_STR_VAR:
if (index >= STROBE_MAX_STRS)
return 1;
ctx->payload += read_str_var(ctx->cfg, index, ctx->tls_base,
ctx->value, ctx->data, ctx->payload);
break;
}
return 0;
}
#endif /* USE_BPF_LOOP */
/*
* read_strobe_meta returns NULL, if no metadata was read; otherwise returns
* pointer to *right after* payload ends
*/
#ifdef SUBPROGS
__noinline
#else
__always_inline
#endif
static void *read_strobe_meta(struct task_struct *task,
struct strobemeta_payload *data)
{
pid_t pid = bpf_get_current_pid_tgid() >> 32;
struct strobe_value_generic value = {0};
struct strobemeta_cfg *cfg;
void *tls_base, *payload;
cfg = bpf_map_lookup_elem(&strobemeta_cfgs, &pid);
if (!cfg)
return NULL;
data->int_vals_set_mask = 0;
data->req_meta_valid = 0;
payload = data->payload;
/*
* we don't have struct task_struct definition, it should be:
* tls_base = (void *)task->thread.fsbase;
*/
tls_base = (void *)task;
#ifdef USE_BPF_LOOP
struct read_var_ctx ctx = {
.cfg = cfg,
.tls_base = tls_base,
.value = &value,
.data = data,
.payload = payload,
};
int err;
ctx.type = READ_INT_VAR;
err = bpf_loop(STROBE_MAX_INTS, read_var_callback, &ctx, 0);
if (err != STROBE_MAX_INTS)
return NULL;
ctx.type = READ_STR_VAR;
err = bpf_loop(STROBE_MAX_STRS, read_var_callback, &ctx, 0);
if (err != STROBE_MAX_STRS)
return NULL;
ctx.type = READ_MAP_VAR;
err = bpf_loop(STROBE_MAX_MAPS, read_var_callback, &ctx, 0);
if (err != STROBE_MAX_MAPS)
return NULL;
#else
#ifdef NO_UNROLL
#pragma clang loop unroll(disable)
#else
#pragma unroll
#endif /* NO_UNROLL */
for (int i = 0; i < STROBE_MAX_INTS; ++i) {
read_int_var(cfg, i, tls_base, &value, data);
}
#ifdef NO_UNROLL
#pragma clang loop unroll(disable)
#else
#pragma unroll
#endif /* NO_UNROLL */
for (int i = 0; i < STROBE_MAX_STRS; ++i) {
payload += read_str_var(cfg, i, tls_base, &value, data, payload);
}
#ifdef NO_UNROLL
#pragma clang loop unroll(disable)
#else
#pragma unroll
#endif /* NO_UNROLL */
for (int i = 0; i < STROBE_MAX_MAPS; ++i) {
payload = read_map_var(cfg, i, tls_base, &value, data, payload);
}
#endif /* USE_BPF_LOOP */
/*
* return pointer right after end of payload, so it's possible to
* calculate exact amount of useful data that needs to be sent
*/
return payload;
}
SEC("raw_tracepoint/kfree_skb")
int on_event(struct pt_regs *ctx) {
pid_t pid = bpf_get_current_pid_tgid() >> 32;
struct strobelight_bpf_sample* sample;
struct task_struct *task;
uint32_t zero = 0;
uint64_t ktime_ns;
void *sample_end;
sample = bpf_map_lookup_elem(&sample_heap, &zero);
if (!sample)
return 0; /* this will never happen */
sample->pid = pid;
bpf_get_current_comm(&sample->comm, TASK_COMM_LEN);
ktime_ns = bpf_ktime_get_ns();
sample->ktime = ktime_ns;
task = (struct task_struct *)bpf_get_current_task();
sample_end = read_strobe_meta(task, &sample->metadata);
sample->has_meta = sample_end != NULL;
sample_end = sample_end ? : &sample->metadata;
if ((ktime_ns >> STACK_TABLE_EPOCH_SHIFT) & 1) {
sample->kernel_stack_id = bpf_get_stackid(ctx, &stacks_1, 0);
sample->user_stack_id = bpf_get_stackid(ctx, &stacks_1, BPF_F_USER_STACK);
} else {
sample->kernel_stack_id = bpf_get_stackid(ctx, &stacks_0, 0);
sample->user_stack_id = bpf_get_stackid(ctx, &stacks_0, BPF_F_USER_STACK);
}
uint64_t sample_size = sample_end - (void *)sample;
/* should always be true */
if (sample_size < sizeof(struct strobelight_bpf_sample))
bpf_perf_event_output(ctx, &samples, 0, sample, 1 + sample_size);
return 0;
}
char _license[] SEC("license") = "GPL";