Recent results in astrochemistry have revealed that some molecules, such as interstellar complex organic species and deuterated species, can serve as valuable tools in the investigation of star-forming regions. Sulphuretted species can also be used to follow the chemical evolution of the early stages of a Sun-like star formation process. The goal is to obtain a census of S-bearing species using interferometric images towards SVS13-A, a Class I object associated with a hot corino that is rich in interstellar complex organic molecules. To this end, we used the NGC1333 SVS13-A data at 3mm and 1.4mm obtained with the IRAM-NOEMA interferometer in the framework of the SOLIS (Seeds of Life in Space) Large Program. The line emission of S-bearing species was imaged and analyzed using local thermodynamic equilibrium (LTE) and large velocity gradient (LVG) approaches. We imaged the spatial distribution on <=300au scale of the line emission of ^32^SO, ^34^SO, C^32^S, C^34^S, C^33^S, OCS, H_2_C^32^S, H_2_C^34^S, and NS. The low excitation (9K) ^32^SO line traces: (i) the low-velocity SVS13-A outflow and (ii) the fast (up to 100km/s away from the systemic velocity) collimated jet driven by the nearby SVS13-B Class 0 object. Conversely, the rest of the lines are confined in the inner SVS13-A region, where complex organics were previously imaged.More specifically, the non-LTE LVG analysis of SO, SO_2_, and H_2_CS indicates a hot corino origin (size in the 60-120au range). Temperatures between 50K and 300K, as well as volume densities larger than 10^5^cm^-3^ have been derived. The abundances of the sulphuretted are in the following ranges: 0.3-6x10^-6^ (CS), 7x10^-9^-1x10^-7^ (SO), 1-10x10^-7^ (SO_2_), a few 10^-10^ (H_2_CS and OCS), and 10^-10^-10^-9^ (NS). The N(NS)/N(NS+) ratio is larger than 10, supporting the assessment that the NS+ ion is mainly formed in the extended envelope. The [H_2_CS]/[H_2_CO] ratio, once measured at high-spatial resolutions, increases with time (from Class 0 to Class II objects) by more than one order of magnitude (from <=10^-2^ to a few 10^-1^). This suggests that [S]/[O] changes along the process of Sun-like star formation. Finally, the estimate of the [S]/[H] budget in SVS13-A is 2%-17% of the Solar System value (1.8x10^-5^), which is consistent with what was previously measured towards Class 0 objects (1%-8%). This finding supports the notion that the enrichment of the sulphuretted species with respect to dark clouds remains constant from the Class 0 to the Class I stages of lowmass star formation. The present findings stress the importance of investigating the chemistry of star-forming regions using large observational surveys as well as sampling regions on the scale of the Solar System.