/*
* Copyright (c) 2014-2018, Intel Corporation
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* * Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
* * Neither the name of Intel Corporation nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#include "pt_encoder.h"
#include "pt_config.h"
#include "pt_opcodes.h"
#include <string.h>
#include <stdlib.h>
int pt_encoder_init(struct pt_encoder *encoder, const struct pt_config *config)
{
int errcode;
if (!encoder)
return -pte_invalid;
memset(encoder, 0, sizeof(*encoder));
errcode = pt_config_from_user(&encoder->config, config);
if (errcode < 0)
return errcode;
encoder->pos = encoder->config.begin;
return 0;
}
void pt_encoder_fini(struct pt_encoder *encoder)
{
(void) encoder;
/* Nothing to do. */
}
struct pt_encoder *pt_alloc_encoder(const struct pt_config *config)
{
struct pt_encoder *encoder;
int errcode;
encoder = malloc(sizeof(*encoder));
if (!encoder)
return NULL;
errcode = pt_encoder_init(encoder, config);
if (errcode < 0) {
free(encoder);
return NULL;
}
return encoder;
}
void pt_free_encoder(struct pt_encoder *encoder)
{
pt_encoder_fini(encoder);
free(encoder);
}
int pt_enc_sync_set(struct pt_encoder *encoder, uint64_t offset)
{
uint8_t *begin, *end, *pos;
if (!encoder)
return -pte_invalid;
begin = encoder->config.begin;
end = encoder->config.end;
pos = begin + offset;
if (end < pos || pos < begin)
return -pte_eos;
encoder->pos = pos;
return 0;
}
int pt_enc_get_offset(const struct pt_encoder *encoder, uint64_t *offset)
{
const uint8_t *raw, *begin;
if (!encoder || !offset)
return -pte_invalid;
/* The encoder is synchronized at all times. */
raw = encoder->pos;
if (!raw)
return -pte_internal;
begin = encoder->config.begin;
if (!begin)
return -pte_internal;
*offset = raw - begin;
return 0;
}
const struct pt_config *pt_enc_get_config(const struct pt_encoder *encoder)
{
if (!encoder)
return NULL;
return &encoder->config;
}
/* Check the remaining space.
*
* Returns zero if there are at least \@size bytes of free space available in
* \@encoder's Intel PT buffer.
*
* Returns -pte_eos if not enough space is available.
* Returns -pte_internal if \@encoder is NULL.
* Returns -pte_internal if \@encoder is not synchronized.
*/
static int pt_reserve(const struct pt_encoder *encoder, unsigned int size)
{
const uint8_t *begin, *end, *pos;
if (!encoder)
return -pte_internal;
/* The encoder is synchronized at all times. */
pos = encoder->pos;
if (!pos)
return -pte_internal;
begin = encoder->config.begin;
end = encoder->config.end;
pos += size;
if (pos < begin || end < pos)
return -pte_eos;
return 0;
}
/* Return the size of an IP payload based on its IP compression.
*
* Returns -pte_bad_packet if \@ipc is not a valid IP compression.
*/
static int pt_ipc_size(enum pt_ip_compression ipc)
{
switch (ipc) {
case pt_ipc_suppressed:
return 0;
case pt_ipc_update_16:
return pt_pl_ip_upd16_size;
case pt_ipc_update_32:
return pt_pl_ip_upd32_size;
case pt_ipc_update_48:
return pt_pl_ip_upd48_size;
case pt_ipc_sext_48:
return pt_pl_ip_sext48_size;
case pt_ipc_full:
return pt_pl_ip_full_size;
}
return -pte_invalid;
}
/* Encode an integer value.
*
* Writes the \@size least signifficant bytes of \@value starting from \@pos.
*
* The caller needs to ensure that there is enough space available.
*
* Returns the updated position.
*/
static uint8_t *pt_encode_int(uint8_t *pos, uint64_t val, int size)
{
for (; size; --size, val >>= 8)
*pos++ = (uint8_t) val;
return pos;
}
/* Encode an IP packet.
*
* Write an IP packet with opcode \@opc and payload from \@packet if there is
* enough space in \@encoder's Intel PT buffer.
*
* Returns the number of bytes written on success.
*
* Returns -pte_eos if there is not enough space.
* Returns -pte_internal if \@encoder or \@packet is NULL.
* Returns -pte_invalid if \@packet.ipc is not valid.
*/
static int pt_encode_ip(struct pt_encoder *encoder, enum pt_opcode op,
const struct pt_packet_ip *packet)
{
uint8_t *pos;
uint8_t opc, ipc;
int size, errcode;
if (!encoder || !packet)
return pte_internal;
size = pt_ipc_size(packet->ipc);
if (size < 0)
return size;
errcode = pt_reserve(encoder, /* opc size = */ 1 + size);
if (errcode < 0)
return errcode;
/* We already checked the ipc in pt_ipc_size(). */
ipc = (uint8_t) (packet->ipc << pt_opm_ipc_shr);
opc = (uint8_t) op;
pos = encoder->pos;
*pos++ = opc | ipc;
encoder->pos = pt_encode_int(pos, packet->ip, size);
return /* opc size = */ 1 + size;
}
int pt_enc_next(struct pt_encoder *encoder, const struct pt_packet *packet)
{
uint8_t *pos, *begin;
int errcode;
if (!encoder || !packet)
return -pte_invalid;
pos = begin = encoder->pos;
switch (packet->type) {
case ppt_pad:
errcode = pt_reserve(encoder, ptps_pad);
if (errcode < 0)
return errcode;
*pos++ = pt_opc_pad;
encoder->pos = pos;
return (int) (pos - begin);
case ppt_psb: {
uint64_t psb;
errcode = pt_reserve(encoder, ptps_psb);
if (errcode < 0)
return errcode;
psb = ((uint64_t) pt_psb_hilo << 48 |
(uint64_t) pt_psb_hilo << 32 |
(uint64_t) pt_psb_hilo << 16 |
(uint64_t) pt_psb_hilo);
pos = pt_encode_int(pos, psb, 8);
pos = pt_encode_int(pos, psb, 8);
encoder->pos = pos;
return (int) (pos - begin);
}
case ppt_psbend:
errcode = pt_reserve(encoder, ptps_psbend);
if (errcode < 0)
return errcode;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_psbend;
encoder->pos = pos;
return (int) (pos - begin);
case ppt_ovf:
errcode = pt_reserve(encoder, ptps_ovf);
if (errcode < 0)
return errcode;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_ovf;
encoder->pos = pos;
return (int) (pos - begin);
case ppt_fup:
return pt_encode_ip(encoder, pt_opc_fup, &packet->payload.ip);
case ppt_tip:
return pt_encode_ip(encoder, pt_opc_tip, &packet->payload.ip);
case ppt_tip_pge:
return pt_encode_ip(encoder, pt_opc_tip_pge,
&packet->payload.ip);
case ppt_tip_pgd:
return pt_encode_ip(encoder, pt_opc_tip_pgd,
&packet->payload.ip);
case ppt_tnt_8: {
uint8_t opc, stop;
if (packet->payload.tnt.bit_size >= 7)
return -pte_bad_packet;
errcode = pt_reserve(encoder, ptps_tnt_8);
if (errcode < 0)
return errcode;
stop = packet->payload.tnt.bit_size + pt_opm_tnt_8_shr;
opc = (uint8_t)
(packet->payload.tnt.payload << pt_opm_tnt_8_shr);
*pos++ = (uint8_t) (opc | (1u << stop));
encoder->pos = pos;
return (int) (pos - begin);
}
case ppt_tnt_64: {
uint64_t tnt, stop;
errcode = pt_reserve(encoder, ptps_tnt_64);
if (errcode < 0)
return errcode;
if (packet->payload.tnt.bit_size >= pt_pl_tnt_64_bits)
return -pte_invalid;
stop = 1ull << packet->payload.tnt.bit_size;
tnt = packet->payload.tnt.payload;
if (tnt & ~(stop - 1))
return -pte_invalid;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_tnt_64;
pos = pt_encode_int(pos, tnt | stop, pt_pl_tnt_64_size);
encoder->pos = pos;
return (int) (pos - begin);
}
case ppt_mode: {
uint8_t mode;
errcode = pt_reserve(encoder, ptps_mode);
if (errcode < 0)
return errcode;
switch (packet->payload.mode.leaf) {
default:
return -pte_bad_packet;
case pt_mol_exec:
mode = pt_mol_exec;
if (packet->payload.mode.bits.exec.csl)
mode |= pt_mob_exec_csl;
if (packet->payload.mode.bits.exec.csd)
mode |= pt_mob_exec_csd;
break;
case pt_mol_tsx:
mode = pt_mol_tsx;
if (packet->payload.mode.bits.tsx.intx)
mode |= pt_mob_tsx_intx;
if (packet->payload.mode.bits.tsx.abrt)
mode |= pt_mob_tsx_abrt;
break;
}
*pos++ = pt_opc_mode;
*pos++ = mode;
encoder->pos = pos;
return (int) (pos - begin);
}
case ppt_pip: {
uint64_t cr3;
errcode = pt_reserve(encoder, ptps_pip);
if (errcode < 0)
return errcode;
cr3 = packet->payload.pip.cr3;
cr3 >>= pt_pl_pip_shl;
cr3 <<= pt_pl_pip_shr;
if (packet->payload.pip.nr)
cr3 |= (uint64_t) pt_pl_pip_nr;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_pip;
pos = pt_encode_int(pos, cr3, pt_pl_pip_size);
encoder->pos = pos;
return (int) (pos - begin);
}
case ppt_tsc:
errcode = pt_reserve(encoder, ptps_tsc);
if (errcode < 0)
return errcode;
*pos++ = pt_opc_tsc;
pos = pt_encode_int(pos, packet->payload.tsc.tsc,
pt_pl_tsc_size);
encoder->pos = pos;
return (int) (pos - begin);
case ppt_cbr:
errcode = pt_reserve(encoder, ptps_cbr);
if (errcode < 0)
return errcode;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_cbr;
*pos++ = packet->payload.cbr.ratio;
*pos++ = 0;
encoder->pos = pos;
return (int) (pos - begin);
case ppt_tma: {
uint16_t ctc, fc;
errcode = pt_reserve(encoder, ptps_tma);
if (errcode < 0)
return errcode;
ctc = packet->payload.tma.ctc;
fc = packet->payload.tma.fc;
if (fc & ~pt_pl_tma_fc_mask)
return -pte_bad_packet;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_tma;
pos = pt_encode_int(pos, ctc, pt_pl_tma_ctc_size);
*pos++ = 0;
pos = pt_encode_int(pos, fc, pt_pl_tma_fc_size);
encoder->pos = pos;
return (int) (pos - begin);
}
case ppt_mtc:
errcode = pt_reserve(encoder, ptps_mtc);
if (errcode < 0)
return errcode;
*pos++ = pt_opc_mtc;
*pos++ = packet->payload.mtc.ctc;
encoder->pos = pos;
return (int) (pos - begin);
case ppt_cyc: {
uint8_t byte[pt_pl_cyc_max_size], index, end;
uint64_t ctc;
ctc = (uint8_t) packet->payload.cyc.value;
ctc <<= pt_opm_cyc_shr;
byte[0] = pt_opc_cyc;
byte[0] |= (uint8_t) ctc;
ctc = packet->payload.cyc.value;
ctc >>= (8 - pt_opm_cyc_shr);
if (ctc)
byte[0] |= pt_opm_cyc_ext;
for (end = 1; ctc; ++end) {
/* Check if the CYC payload is too big. */
if (pt_pl_cyc_max_size <= end)
return -pte_bad_packet;
ctc <<= pt_opm_cycx_shr;
byte[end] = (uint8_t) ctc;
ctc >>= 8;
if (ctc)
byte[end] |= pt_opm_cycx_ext;
}
errcode = pt_reserve(encoder, end);
if (errcode < 0)
return errcode;
for (index = 0; index < end; ++index)
*pos++ = byte[index];
encoder->pos = pos;
return (int) (pos - begin);
}
case ppt_stop:
errcode = pt_reserve(encoder, ptps_stop);
if (errcode < 0)
return errcode;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_stop;
encoder->pos = pos;
return (int) (pos - begin);
case ppt_vmcs:
errcode = pt_reserve(encoder, ptps_vmcs);
if (errcode < 0)
return errcode;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_vmcs;
pos = pt_encode_int(pos,
packet->payload.vmcs.base >> pt_pl_vmcs_shl,
pt_pl_vmcs_size);
encoder->pos = pos;
return (int) (pos - begin);
case ppt_mnt:
errcode = pt_reserve(encoder, ptps_mnt);
if (errcode < 0)
return errcode;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_ext2;
*pos++ = pt_ext2_mnt;
pos = pt_encode_int(pos, packet->payload.mnt.payload,
pt_pl_mnt_size);
encoder->pos = pos;
return (int) (pos - begin);
case ppt_exstop: {
uint8_t ext;
errcode = pt_reserve(encoder, ptps_exstop);
if (errcode < 0)
return errcode;
ext = packet->payload.exstop.ip ?
pt_ext_exstop_ip : pt_ext_exstop;
*pos++ = pt_opc_ext;
*pos++ = ext;
encoder->pos = pos;
return (int) (pos - begin);
}
case ppt_mwait:
errcode = pt_reserve(encoder, ptps_mwait);
if (errcode < 0)
return errcode;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_mwait;
pos = pt_encode_int(pos, packet->payload.mwait.hints,
pt_pl_mwait_hints_size);
pos = pt_encode_int(pos, packet->payload.mwait.ext,
pt_pl_mwait_ext_size);
encoder->pos = pos;
return (int) (pos - begin);
case ppt_pwre: {
uint64_t payload;
errcode = pt_reserve(encoder, ptps_pwre);
if (errcode < 0)
return errcode;
payload = 0ull;
payload |= ((uint64_t) packet->payload.pwre.state <<
pt_pl_pwre_state_shr) &
(uint64_t) pt_pl_pwre_state_mask;
payload |= ((uint64_t) packet->payload.pwre.sub_state <<
pt_pl_pwre_sub_state_shr) &
(uint64_t) pt_pl_pwre_sub_state_mask;
if (packet->payload.pwre.hw)
payload |= (uint64_t) pt_pl_pwre_hw_mask;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_pwre;
pos = pt_encode_int(pos, payload, pt_pl_pwre_size);
encoder->pos = pos;
return (int) (pos - begin);
}
case ppt_pwrx: {
uint64_t payload;
errcode = pt_reserve(encoder, ptps_pwrx);
if (errcode < 0)
return errcode;
payload = 0ull;
payload |= ((uint64_t) packet->payload.pwrx.last <<
pt_pl_pwrx_last_shr) &
(uint64_t) pt_pl_pwrx_last_mask;
payload |= ((uint64_t) packet->payload.pwrx.deepest <<
pt_pl_pwrx_deepest_shr) &
(uint64_t) pt_pl_pwrx_deepest_mask;
if (packet->payload.pwrx.interrupt)
payload |= (uint64_t) pt_pl_pwrx_wr_int;
if (packet->payload.pwrx.store)
payload |= (uint64_t) pt_pl_pwrx_wr_store;
if (packet->payload.pwrx.autonomous)
payload |= (uint64_t) pt_pl_pwrx_wr_hw;
*pos++ = pt_opc_ext;
*pos++ = pt_ext_pwrx;
pos = pt_encode_int(pos, payload, pt_pl_pwrx_size);
encoder->pos = pos;
return (int) (pos - begin);
}
case ppt_ptw: {
uint8_t plc, ext;
int size;
plc = packet->payload.ptw.plc;
size = pt_ptw_size(plc);
if (size < 0)
return size;
errcode = pt_reserve(encoder, pt_opcs_ptw + size);
if (errcode < 0)
return errcode;
ext = pt_ext_ptw;
ext |= plc << pt_opm_ptw_pb_shr;
if (packet->payload.ptw.ip)
ext |= (uint8_t) pt_opm_ptw_ip;
*pos++ = pt_opc_ext;
*pos++ = ext;
pos = pt_encode_int(pos, packet->payload.ptw.payload, size);
encoder->pos = pos;
return (int) (pos - begin);
}
case ppt_unknown:
case ppt_invalid:
return -pte_bad_opc;
}
return -pte_bad_opc;
}
int pt_encode_pad(struct pt_encoder *encoder)
{
struct pt_packet packet;
packet.type = ppt_pad;
return pt_enc_next(encoder, &packet);
}
int pt_encode_psb(struct pt_encoder *encoder)
{
struct pt_packet packet;
packet.type = ppt_psb;
return pt_enc_next(encoder, &packet);
}
int pt_encode_psbend(struct pt_encoder *encoder)
{
struct pt_packet packet;
packet.type = ppt_psbend;
return pt_enc_next(encoder, &packet);
}
int pt_encode_tip(struct pt_encoder *encoder, uint64_t ip,
enum pt_ip_compression ipc)
{
struct pt_packet packet;
packet.type = ppt_tip;
packet.payload.ip.ip = ip;
packet.payload.ip.ipc = ipc;
return pt_enc_next(encoder, &packet);
}
int pt_encode_tnt_8(struct pt_encoder *encoder, uint8_t tnt, int size)
{
struct pt_packet packet;
packet.type = ppt_tnt_8;
packet.payload.tnt.bit_size = (uint8_t) size;
packet.payload.tnt.payload = tnt;
return pt_enc_next(encoder, &packet);
}
int pt_encode_tnt_64(struct pt_encoder *encoder, uint64_t tnt, int size)
{
struct pt_packet packet;
packet.type = ppt_tnt_64;
packet.payload.tnt.bit_size = (uint8_t) size;
packet.payload.tnt.payload = tnt;
return pt_enc_next(encoder, &packet);
}
int pt_encode_tip_pge(struct pt_encoder *encoder, uint64_t ip,
enum pt_ip_compression ipc)
{
struct pt_packet packet;
packet.type = ppt_tip_pge;
packet.payload.ip.ip = ip;
packet.payload.ip.ipc = ipc;
return pt_enc_next(encoder, &packet);
}
int pt_encode_tip_pgd(struct pt_encoder *encoder, uint64_t ip,
enum pt_ip_compression ipc)
{
struct pt_packet packet;
packet.type = ppt_tip_pgd;
packet.payload.ip.ip = ip;
packet.payload.ip.ipc = ipc;
return pt_enc_next(encoder, &packet);
}
int pt_encode_fup(struct pt_encoder *encoder, uint64_t ip,
enum pt_ip_compression ipc)
{
struct pt_packet packet;
packet.type = ppt_fup;
packet.payload.ip.ip = ip;
packet.payload.ip.ipc = ipc;
return pt_enc_next(encoder, &packet);
}
int pt_encode_pip(struct pt_encoder *encoder, uint64_t cr3, uint8_t flags)
{
struct pt_packet packet;
packet.type = ppt_pip;
packet.payload.pip.cr3 = cr3;
packet.payload.pip.nr = (flags & pt_pl_pip_nr) != 0;
return pt_enc_next(encoder, &packet);
}
int pt_encode_ovf(struct pt_encoder *encoder)
{
struct pt_packet packet;
packet.type = ppt_ovf;
return pt_enc_next(encoder, &packet);
}
int pt_encode_mode_exec(struct pt_encoder *encoder, enum pt_exec_mode mode)
{
struct pt_packet packet;
packet.type = ppt_mode;
packet.payload.mode.leaf = pt_mol_exec;
packet.payload.mode.bits.exec = pt_set_exec_mode(mode);
return pt_enc_next(encoder, &packet);
}
int pt_encode_mode_tsx(struct pt_encoder *encoder, uint8_t bits)
{
struct pt_packet packet;
packet.type = ppt_mode;
packet.payload.mode.leaf = pt_mol_tsx;
if (bits & pt_mob_tsx_intx)
packet.payload.mode.bits.tsx.intx = 1;
else
packet.payload.mode.bits.tsx.intx = 0;
if (bits & pt_mob_tsx_abrt)
packet.payload.mode.bits.tsx.abrt = 1;
else
packet.payload.mode.bits.tsx.abrt = 0;
return pt_enc_next(encoder, &packet);
}
int pt_encode_tsc(struct pt_encoder *encoder, uint64_t tsc)
{
struct pt_packet packet;
packet.type = ppt_tsc;
packet.payload.tsc.tsc = tsc;
return pt_enc_next(encoder, &packet);
}
int pt_encode_cbr(struct pt_encoder *encoder, uint8_t cbr)
{
struct pt_packet packet;
packet.type = ppt_cbr;
packet.payload.cbr.ratio = cbr;
return pt_enc_next(encoder, &packet);
}
int pt_encode_tma(struct pt_encoder *encoder, uint16_t ctc, uint16_t fc)
{
struct pt_packet packet;
packet.type = ppt_tma;
packet.payload.tma.ctc = ctc;
packet.payload.tma.fc = fc;
return pt_enc_next(encoder, &packet);
}
int pt_encode_mtc(struct pt_encoder *encoder, uint8_t ctc)
{
struct pt_packet packet;
packet.type = ppt_mtc;
packet.payload.mtc.ctc = ctc;
return pt_enc_next(encoder, &packet);
}
int pt_encode_cyc(struct pt_encoder *encoder, uint32_t ctc)
{
struct pt_packet packet;
packet.type = ppt_cyc;
packet.payload.cyc.value = ctc;
return pt_enc_next(encoder, &packet);
}
int pt_encode_stop(struct pt_encoder *encoder)
{
struct pt_packet packet;
packet.type = ppt_stop;
return pt_enc_next(encoder, &packet);
}
int pt_encode_vmcs(struct pt_encoder *encoder, uint64_t payload)
{
struct pt_packet packet;
packet.type = ppt_vmcs;
packet.payload.vmcs.base = payload;
return pt_enc_next(encoder, &packet);
}
int pt_encode_mnt(struct pt_encoder *encoder, uint64_t payload)
{
struct pt_packet packet;
packet.type = ppt_mnt;
packet.payload.mnt.payload = payload;
return pt_enc_next(encoder, &packet);
}